Experimental and theoretical combustion data in XML format

The database contains 93326 data points in 1396 XML-format data files.
Last update: 13.09.2017
ReSpecTh Kinetics Data Format Specification v2.0

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XML fileFile DOIBibliographyData TypeInitial Composition
g00000001psr.xml 10.24388/ g00000001psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 1. H2 open diamond, H2O open circle jet stirred reactor measurement H2 O2 N2
g00000001_x.xml 10.24388/ g00000001_x Chaumeix, N., Pichon, S., Lafosse, F., Paillard, C.-E., International Journal of Hydrogen Energy, 2007, (32) 2216-2226, Fig. 12., left, open diamond ignition delay measurement H2 O2 Ar
g00000002psr.xml 10.24388/ g00000002psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 2. H2 open diamond, H2O open circle jet stirred reactor measurement H2 O2 N2
g00000002_x.xml 10.24388/ g00000002_x Chaumeix, N., Pichon, S., Lafosse, F., Paillard, C.-E., International Journal of Hydrogen Energy 2007, (32) 2216-2226, Fig. 12., center, open diamond ignition delay measurement H2 O2 Ar
g00000003psr.xml 10.24388/ g00000003psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 3. H2 open diamond, H2O open circle jet stirred reactor measurement H2 O2 N2
g00000003_x.xml 10.24388/ g00000003_x Chaumeix, N., Pichon, S., Lafosse, F., Paillard, C.-E., International Journal of Hydrogen Energy, 2007, (32) 2216-2226, Fig. 12., right, open diamond ignition delay measurement H2 O2 Ar
g00000004psr_x.xml 10.24388/ g00000004psr_x Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 4. H2 open diamond, H2O open circle jet stirred reactor measurement H2 O2 N2
g00000005psr.xml 10.24388/ g00000005psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 5. H2 open diamond, H2O open circle jet stirred reactor measurement H2 O2 N2
g00000006psr.xml 10.24388/ g00000006psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 6. H2 open diamond, O2 open circle jet stirred reactor measurement H2 O2 N2 H2O
g00000007.xml 10.24388/ g00000007 Pang, G.A., Davison, D.F., Hanson, R.K., Proceedings of the Combustion Institute, 2009, (32), 181-188, Fig. 3., full square ignition delay measurement H2 O2 Ar
g00000007psr.xml 10.24388/ g00000007psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 7. H2 open diamond, O2 open circle jet stirred reactor measurement H2 O2 N2 H2O
g00000008.xml 10.24388/ g00000008 Pang, G.A., Davison, D.F., Hanson, R.K., Proceedings of the Combustion Institute, 2009, (32), 181-188, Fig. 5., full square ignition delay measurement H2 O2 Ar
g00000008psr.xml 10.24388/ g00000008psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 8. H2 open diamond, O2 open circle jet stirred reactor measurement H2 O2 N2 H2O
g00000009.xml 10.24388/ g00000009 Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 12., full triangle ignition delay measurement H2 O2 Ar
g00000009psr.xml 10.24388/ g00000009psr Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 9. H2 open diamond, O2 open circle jet stirred reactor measurement H2 O2 N2 H2O
g00000010.xml 10.24388/ g00000010 Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 12., full circle ignition delay measurement H2 O2 Ar
g00000011_x.xml 10.24388/ g00000011_x Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 12., full square ignition delay measurement H2 O2 Ar
g00000012.xml 10.24388/ g00000012 Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 13., full triangle ignition delay measurement H2 O2 Ar
g00000013.xml 10.24388/ g00000013 Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 13., full circle ignition delay measurement H2 O2 Ar
g00000014_x.xml 10.24388/ g00000014_x Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 13., full square ignition delay measurement H2 O2 Ar
gal_fl_1.xml 10.24388/ gal_fl_1 Koroll, G.W., Kumar, R.K., Bowles, E.M., Combustion and Flame, 1993, (94), (3), 330-340., Fig. 4., full circle laminar burning velocity measurement H2 O2 N2
gal_fl_3.xml 10.24388/ gal_fl_3 Bradley, Lawes, D.M., Liu, K., Verhelst, S., Woolley, R., Combustion and Flame 2007, (149), (1-2), 162-172., Fig. 10., open circle, 0.1 MPa laminar burning velocity measurement H2 O2 N2
gal_fl_4.xml 10.24388/ gal_fl_4 Bradley, Lawes, D.M., Liu, K., Verhelst, S., Woolley, R., Combustion and Flame 2007, (149), (1-2), 162-172., Fig. 10., open circle, 0.5 MPa laminar burning velocity measurement H2 O2 N2
gal_fl_5.xml 10.24388/ gal_fl_5 Bradley, Lawes, D.M., Liu, K., Verhelst, S., Woolley, R., Combustion and Flame 2007, (149), (1-2), 162-172., Fig. 10., open circle, 1 MPa laminar burning velocity measurement H2 O2 N2
k00000001.xml 10.24388/ k00000001 Masten, D.A., Hanson, R.K., Bowman, C.T., Journal of Physical Chemistry, 1990, (94), 7119-7128., Table II. Rate coefficient determination - H + O2 = OH + O  
k00000002.xml 10.24388/ k00000002 Masten, D.A., Hanson, R.K., Bowman, C.T., Journal of Physical Chemistry, 1990, (94), 7119-7128., Table III. Rate coefficient determination - H + O2 = OH + O  
k00000003.xml 10.24388/ k00000003 Du, H., Hessler, J.P., Journal of Chemical Physics, 1992, (96), 1077-1092., Table II. Rate coefficient determination - H + O2 = OH + O  
k00000004.xml 10.24388/ k00000004 Yang, H, Gardiner, W.C., Shin, K.S., Fujii, N., Chemical Physics Letters, 1994, (231), (4-6), 449-453., Table 2. Rate coefficient determination - H + O2 = OH + O  
k00000005.xml 10.24388/ k00000005 Ryu, S.O., Hwang, S.M., Rabinowitz, M.J., Journal of Physical Chemistry, 1995, (99), 13984-13991., Table 1. Rate coefficient determination - H + O2 = OH + O  
k00000006.xml 10.24388/ k00000006 Mueller, M.A., Yetter, R.A., Dryer,F.L., Proceedings of the Combustion Institute, 1998, (27), 177-184., Table 1. Rate coefficient determination - LP H + O2 + M = HO2 + M  
k00000007.xml 10.24388/ k00000007 Mueller, M.A., Yetter, R.A., Dryer,F.L., Proceedings of the Combustion Institute, 1998, (27), 177-184., Table 1. Rate coefficient determination - LP H + O2 + M = HO2 + M  
k00000008.xml 10.24388/ k00000008 Pirraglia, A.N., Michael, J.V., Sutherland, J.W., Klemm, R.B., Journal of Physical Chemistry, 1989, (93), 282-291., Table I. Rate coefficient determination - H + O2 = OH + O  
k00000009.xml 10.24388/ k00000009 Shin, K.S., Michael,J.V., Journal of Chemical Physics, 1991, (95), 262-273., Table I. Rate coefficient determination - H + O2 = OH + O  
k00000010.xml 10.24388/ k00000010 Ashman, P.J., Haynes, B.S., Proceedings of the Combustion Institute, 1998, (27), 185-191., Fig. 5., full inverse triangle Rate coefficient determination - LP H + O2 + M = HO2 + M  
k00000012.xml 10.24388/ k00000012 Hwang, S.M., Ryu, S.O., De Witt, K.J., Rabinowitz, M.J., Chemical Physics Letters, 2005, (408), (1-3), 107-111., Fig. 3., open circle Rate coefficient determination - H + O2 = OH + O  
k00000013.xml 10.24388/ k00000013 Getzinger, R.W., Schott,G.L., Journal of Chemical Physics, 1965, (43), (9), 3237-3247., Table III. Rate coefficient determination - LPH+O2+M=HO2+M  
k00000014.xml 10.24388/ k00000014 Getzinger, R.W., Blair, L.S., Combustion and Flame, 1969, (13), (3), 271-284., Table 2. Rate coefficient determination - LPH+O2+M=HO2+M  
k00000015.xml 10.24388/ k00000015 Blair,L.S., Getzinger, R.W., Combustion and Flame, 1970, (14), (1), 5-12., Table 2. Rate coefficient determination - LPH+O2+M=HO2+M  
k00000016.xml 10.24388/ k00000016 Michael, J.V., Su, M.-C., Sutherland, J.W., Carroll, J.J., A. F. Wagner, Journal of Physical Chemistry A, 2002, (106), 5297-5313., Fig. 5., H + O2 + N2 Rate coefficient determination - LPH+O2+M=HO2+M  
k00000017.xml 10.24388/ k00000017 Michael, J.V., Su, M.-C., Sutherland, J.W., Carroll, J.J., A. F. Wagner, Journal of Physical Chemistry A, 2002, (106), 5297-5313., Fig. 5., H + O2 + Ar Rate coefficient determination - LPH+O2+M=HO2+M  
k00000018.xml 10.24388/ k00000018 Sutherland, J.W., Michael, J.V., Pirraglia, A.N., Nesbitt, F.L., Klemm, R.B., Proceedings of the Combustion Institute 1986, (21), 929-941., Table I. Rate coefficient determination - O + H2 = OH + H  
k00000019.xml 10.24388/ k00000019 Ryu, S.O., Hwang, S.M., Rabinowitz, M.J., Chemical Physics Letters, 1995, (242), (3), 279_284., Table 1. Rate coefficient determination - O + H2 = OH + H  
k00000020.xml 10.24388/ k00000020 Davidson, D.F., Hanson, R.K., Combustion and Flame, 1990, (82), (3_4), 445_447., Fig. 2., full circle + open diamond Rate coefficient determination - O + H2 = OH + H  
k00000021.xml 10.24388/ k00000021 Presser, N., Gordon, R.J., Journal of Chemical Physics, 1985, (82), (3), 1291_297., Table I. Rate coefficient determination - O + H2 = OH + H  
k00000022.xml 10.24388/ k00000022 Light, G.C., Matsumoto, J.H., International Journal of Chemical Kinetics, 1980, (12), (7), 451_468. Rate coefficient determination - O + H2 = OH + H  
k00000023.xml 10.24388/ k00000023 Michael, J.V., Sutherland, J.W., Journal of Physical Chemistry, 1988, (92), 3853-3857., Table I. Rate coefficient determination - H + H2O = OH + H2  
k00000024.xml 10.24388/ k00000024 Oldenborg, R.C., Loge, G.W., Harradine, D.M., Winn, K.R., Journal of Chemical Physics, 1992, (96), 8426-8430., Table I. Rate coefficient determination - OH+H2=H+H2O  
k00000025.xml 10.24388/ k00000025 Davidson, D.F., Chang, A.Y., Hanson,R.K., Symposium (International) on Combustion, 1989, (22), (1), 1877-1885., Fig. 7., full diamond + full triangle + full square Rate coefficient determination - H + H2O = OH + H2  
k00000026.xml 10.24388/ k00000026 Frank, Ber. Bunsenges. Phys. Chem. 1985, p. 186, Fig. 10, Curve II Rate coefficient determination - OH+H2=H+H2O  
k00000027.xml 10.24388/ k00000027 Ravishankara, A.R., Nicovich, J.M., Thompson, R.L., Tully, F.P., Journal of Physical Chemistry, 1981, (85), 2498-2503., Table I. Rate coefficient determination - OH+H2=H+H2O  
k00000028.xml 10.24388/ k00000028 Tully, F.P., Ravishankara, A.R., Journal of Physical Chemistry, 1980, (84), 3126-3130., Table I. Rate coefficient determination - OH+H2=H+H2O  
k00000032.xml 10.24388/ k00000032 Hong, Z., Farooq, A., Barbour, E.A., Davidson, D.F., Hanson, R.K., Journal of Physical Chemistry A, 2009, (113), 12919-12925., Table 1. Rate coefficient determination - H2O2 + M = 2OH + M Ar H2O H2O2
k00000033.xml 10.24388/ k00000033 Hong, Z., Cook, R.D., Davidson, D.F., Hanson, R.K., Journal of Physical Chemistry A, 2010, (114), 5718-5727., Table 1. Rate coefficient determination - H2O2 + M = 2OH + M Ar H2O H2O2
k00000034.xml 10.24388/ k00000034 Michael, J.V., Sutherland, J.W., Harding, L.B., Wagner, A.F., Proceedings of the Combustion Institute, 2000, (28), 1471-1478., Table 2. Rate coefficient determination - H2 + O2 = HO2 + H  
k00000035.xml 10.24388/ k00000035 Javoy, S., Naudet, V., Abid, S., Paillard, C.E., International Journal of Chemical Kinetics, (32), 686-695, 2000, Table III. Rate coefficient determination - O + H2 = OH + H  
k00000036.xml 10.24388/ k00000036 K. Natarjan, K., Roth, P., Combustion and Flame, (70), 267-279, 1987, Table 1. Rate coefficient determination - O + H2 = OH + H  
k00000037.xml 10.24388/ k00000037 K. Natarjan, K., Roth, P., Combustion and Flame, (70), 267-279, 1987, Table 2. Rate coefficient determination - O + H2 = OH + H  
k00000038.xml 10.24388/ k00000038 Sutherland, J.W., Michael, J.V., Pirraglia, A.N., Nesbitt, F.L., Klemm, R.B., Twenty-first Symposium (International) on Combustion/The Combustion Institute, 929-941, 1986, Table I. Rate coefficient determination - O + H2 = OH + H  
k00000039.xml 10.24388/ k00000039 Davidson, D.F., Hanson, R.K., Combustion and Flame, (82), 445-447, 1990, Table II. Rate coefficient determination - O + H2 = OH + H  
k00000041.xml 10.24388/ k00000041 Hippler, H., Neunaber, H., Troe, J., Journal of Chemical Physics, (103), 3510-3516, 1995, Table I. Rate coefficient determination - HO2 + OH = H2O + O2  
k00000042.xml 10.24388/ k00000042 Hong, Z., Vasu, S.S., Davidson, D.F., Hanson, R.K., Journal of Physical Chemistry A, (114), 5520-5525, 2010, Fig. 6. Rate coefficient determination - H2O + O2 = HO2 + OH  
k00000045.xml 10.24388/ k00000045 Kappel, Ch., Luther, K., Troe, J., Physical Chemistry Chemical Physics, (4), 4392-4398, 2002, Table 1. Rate coefficient determination - H2O2 (+ M) = 2OH (+ M) Ar H2O2
k00000046.xml 10.24388/ k00000046 Kappel, Ch., Luther, K., Troe, J., Physical Chemistry Chemical Physics, (4), 4392-4398, 2002, Table 1. Rate coefficient determination - H2O2 (+ M) = 2OH (+ M) Ar H2O2
k00000047.xml 10.24388/ k00000047 Kappel, Ch., Luther, K., Troe, J., Physical Chemistry Chemical Physics, (4), 4392-4398, 2002, Table 1. Rate coefficient determination - H2O2 (+ M) = 2OH (+ M) Ar H2O2
k00000050.xml 10.24388/ k00000050 Hong,Z., Davidson, D.F., Barbour, E.A., Hanson, R.K., Proceedings of the Combustion Institute 2011, (33), 309-316, Fig. 5., full circle, data from the supplement Rate coefficient determination - H+O2=OH+O  
k00000052.xml 10.24388/ k00000052 Hong, Z., Lam, K-Y., Sur, R., Wang, S., Davidson, D. F., Hanson, R. K., Proceedings of the Combustion Institute, 2012, Supplementary Material, Table S-1. Rate coefficient determination - HO2 + OH = H2O + O2  
k00000053.xml 10.24388/ k00000053 Hong, Z., Lam, K-Y., Sur, R., Wang, S., Davidson, D. F., Hanson, R. K., Proceedings of the Combustion Institute, 2012, Supplementary Material, Table S-1. Rate coefficient determination - 2HO2 = H2O2 + O2 H2O2
k00000057.xml 10.24388/ k00000057 Yang, Chemical Physics Letters, 1993, p. 72, Fig. 3 Rate coefficient determination - O+H2=OH+H  
k00000060.xml 10.24388/ k00000060 Lam, K-Y., Davidson, D.F., Hanson, R.K., Journal of Chemical Kinetics, 2012, Table 2, sorted by T Rate coefficient determination - OH + H2 = H + H2O  
k00000061.xml 10.24388/ k00000061 H. Hippler; J. Troe; J. Willner, Journal of Chemical Physics 1990, 93, 1755-1760, Fig. 4, full square: from H2O2 thermal decomposition experiments Rate coefficient determination - 2HO2 = H2O2 + O2  
k00000062.xml 10.24388/ k00000062 H. Hippler; J. Troe; J. Willner, Journal of Chemical Physics 1990, 93, 1755-1760, Fig. 4, open square: from experiments with (CH3O)2/O2 mixtures Rate coefficient determination - 2HO2 = H2O2 + O2  
k00000063.xml 10.24388/ k00000063 C. Kappel; K. Luther; J. Troe, Physical Chemistry Chemical Physics 2002, 4, 4392-4398, Table 1a Rate coefficient determination - 2HO2 = H2O2 + O2  
k00000064.xml 10.24388/ k00000064 Table 10, Data from Baldwin et al. in different publications; partly averaged Rate coefficient determination - H2O2+H =H2+HO2  
k00000070.xml 10.24388/ k00000070 C. J. Halstead; D. R. Jenkins, Symposium (International) on Combustion 1969, 12, (1), 979-987, Table I Rate coefficient determination - H + OH + M = H2O + M  
k00000071.xml 10.24388/ k00000071 C. J. Halstead; D. R. Jenkins, Symposium (International) on Combustion 1969, 12, (1), 979-987, Table I Rate coefficient determination - H + OH + M = H2O + M  
k00000072.xml 10.24388/ k00000072 C. J. Halstead; D. R. Jenkins, Symposium (International) on Combustion 1969, 12, (1), 979-987, Table I Rate coefficient determination - H + OH + M = H2O + M  
k00000075.xml 10.24388/ k00000075 Z. Hong; D. F. Davidson; K.-Y. Lam; R. K. Hanson, Combustion and Flame 2012, 159, (10), 3007-3013, Table 1. Rate coefficient determination - H2O2(+M) = 2OH(+M) H2O2 CH4 Ar
k00000081.xml 10.24388/ k00000081 A. Gay; N. H. Pratt, Proc. Int. Symp. Shock Tubes Waves 1971, 8, Fig. 9, open circle Rate coefficient determination - LP H+O2+M=HO2+M  
k00000083.xml 10.24388/ k00000083 N. K. Srinivasan; M.-C. Su; J. W. Sutherland; J. V. Michael; B. Ruscic, The Journal of Physical Chemistry A 2006, 110, (21), 6602-6607, Table 2 Rate coefficient determination - HO2 + OH = H2O + O2  
k10001001.xml 10.24388/ k10001001 M. S. Wooldridge; R. K. Hanson; C. T. Bowman, Symposium (International) on Combustion 1994, 25, (1), 741-748, Table 2 Rate coefficient determination - CO + OH = CO2 + H  
k10001002.xml 10.24388/ k10001002 A. A. Westenberg; N. deHaas, The Journal of Chemical Physics 1973, 58, (10), 4061-4065, Table I Rate coefficient determination - CO + OH = CO2 + H  
k10001003.xml 10.24388/ k10001003 A. R. Ravishankara; R. L. Thompson, Chemical Physics Letters 1983, 99, (5-6), 377-381, Table 1 Rate coefficient determination - CO + OH = CO2 + H  
k10001004.xml 10.24388/ k10001004 T. A. Brabbs; F. E. Belles; R. S. Brokaw, Proceedings of The Combustion Institute 1970, 13, 129-136, Table V Rate coefficient determination - CO + OH = CO2 + H H2 CO O2 CO2 Ar
k10001005.xml 10.24388/ k10001005 D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series A: 4.0% H2-0.5% O2-3.0% CO2-Ar Rate coefficient determination - CO + OH = CO2 + H H2 CO2 O2 Ar
k10001006.xml 10.24388/ k10001006 D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series B: 2.0% H2-0.5% O2-5.0% CO2-Ar Rate coefficient determination - CO + OH = CO2 + H H2 CO2 O2 Ar
k10001007.xml 10.24388/ k10001007 D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series C: 2.0% H2-0.5% O2-7.0% CO2-Ar Rate coefficient determination - CO + OH = CO2 + H H2 CO2 O2 Ar
k10001008.xml 10.24388/ k10001008 D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series D: 2.0% H2-1.0% O2-5.0% CO2-Ar Rate coefficient determination - CO + OH = CO2 + H H2 CO2 O2 Ar
k10001009.xml 10.24388/ k10001009 D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series E: 2.0% H2-2.0% O2-7.0% CO2-Ar Rate coefficient determination - CO + OH = CO2 + H H2 CO2 O2 Ar
k10001013.xml 10.24388/ k10001013 W. C. Gardiner Jr; W. G. Mallard; M. McFarland; K. Morinaga; J. H. Owen; W. T. Rawlins; T. Takeyama; B. F. Walker, Symposium (International) on Combustion 1973, 14, (1), 61-75, Figure 7, cross Rate coefficient determination - CO + OH = CO2 + H  
k10001014.xml 10.24388/ k10001014 M. S. Wooldridge; R. K. Hanson; C. T. Bowman, International Journal of Chemical Kinetics 1996, 28, (5), 361-372, Fig. 5 Rate coefficient determination - CO + OH = CO2 + H  
k10001015.xml 10.24388/ k10001015 J. Vandooren; J. Peeters; P. J. V. Tiggelen, Symposium (International) on Combustion 1975, 15, (1), 745-753, Fig. 4, full circle Rate coefficient determination - CO + OH = CO2 + H H2 CO O2
k10001016.xml 10.24388/ k10001016 J. Peeters; G. Mahnen, Symposium (International) on Combustion 1973, 14, (1), 133-146, Fig. 5, k6 Rate coefficient determination - CO + OH = CO2 + H  
k10001017.xml 10.24388/ k10001017 K. H. Eberius; K. Hoyermann; H. C. Wagner, Symposium (International) on Combustion 1973, 14, (1), 147-156, Fig. 9, open circle, from CO profile Rate coefficient determination - CO + OH = CO2 + H  
k10001018.xml 10.24388/ k10001018 K. H. Eberius; K. Hoyermann; H. C. Wagner, Symposium (International) on Combustion 1973, 14, (1), 147-156, Fig. 9, full circle, from CO2 profile Rate coefficient determination - CO + OH = CO2 + H  
k10003001.xml 10.24388/ k10003001 J.F. Bott, N. Cohen, Int. J. Chem. Kinet. 1991, 23, 1075-1094, see text Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003002.xml 10.24388/ k10003002 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S1, X_C2H5OH = 9.383e-5, X_tBH Sol`n = 2.536e-5 Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003003.xml 10.24388/ k10003003 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S1, X_C2H5OH = 9.383e-5, X_tBH Sol`n = 2.536e-5 Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003004.xml 10.24388/ k10003004 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S1, X_C2H5OH = 4.885e-5, X_tBH Sol`n = 1.394e-5 Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003007.xml 10.24388/ k10003007 W.P. Hess, F.P. Tully, Chem. Phys. Lett. (1988), 152, 183-189, Table 1, 16OH Rate coefficient determination - C2H5OH+OH=CH3CH2O+H2O  
k10003008.xml 10.24388/ k10003008 W.P. Hess, F.P. Tully, Chem. Phys. Lett. (1988), 152, 183-189, Table 1, 18OH, only 599 K data point Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003009.xml 10.24388/ k10003009 K. Lorenz, D. Rhaesa, R. Zellner, private communication (1984), in: R. Atkinson, Chem. Rev. 86 (1986) 69, Fig. 72, cross Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003010.xml 10.24388/ k10003010 S.A. Carr, M.A. Blitz, P.W. Seakins, J Chem. Phys. A 115 (2011) 3335-3345, Table 1, CH3CH2OH Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003011.xml 10.24388/ k10003011 S.A. Carr, M.A. Blitz, P.W. Seakins, J Chem. Phys. A 115 (2011) 3335-3345, Table 3, OH + CH3CH2OH (sorted) Rate coefficient determination - C2H5OH+OH=CH3CH2O+H2O  
k10003012.xml 10.24388/ k10003012 I. Stranic, G.A. Pang, R.K. Hanson, D.M. Golden, C.T. Bowman, J. Chem. Phys. A 118 (2014) 822-828, Table 1 Rate coefficient determination - C2H5OH+OH=PRODUCTS  
k10003013.xml 10.24388/ k10003013 I. Stranic, G.A. Pang, R.K. Hanson, D.M. Golden, C.T. Bowman, J. Chem. Phys. A 118 (2014) 822-828, Table 2 Rate coefficient determination - C2H5OH+OH=CH3CH2O+H2O  
k10005001.xml 10.24388/ k10005001 F.P. Tully, Chem. Phys. Lett., 143, 5, 510-514, Table 1 Rate coefficient determination - C2H4+OH=C2H3+H2O  
k10005002.xml 10.24388/ k10005002 A. Bhargava, P.R. Westmoreland, Combust. Flame, 1998, 113, 333-347, Fig. 16, open circle Rate coefficient determination - C2H4+OH=C2H3+H2O  
k13002001.xml 10.24388/ k13002001 N.K. Srinivasan, M.-C. Su, J.V. Michael, J. Phys. Chem. A 111 (2007) 3951-3958, Table 4, k4 Rate coefficient determination - CH3+OH=S-CH2+H2O  
k20001001.xml 10.24388/ k20001001 Y. Hidaka; T. Taniguchi; T. Kamesawa; H. Masaoka; K. Inami; H. Kawano, International Journal of Chemical Kinetics 1993, 25, (4), 305-322, Fig. 3, open circle, full square, open triangle, full circle and half-open circles Rate coefficient determination - LP HCO + M = CO + H + M  
k20001002.xml 10.24388/ k20001002 I. M. Campbell; B. J. Handy, Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry in Condensed Phases 1978, 74, 316-325, Table 1, M = N2 Rate coefficient determination - CO + H + M = HCO + M  
k20001003.xml 10.24388/ k20001003 I. M. Campbell; B. J. Handy, Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry in Condensed Phases 1978, 74, 316-325, Table 1, M = Ar Rate coefficient determination - CO + H + M = HCO + M  
k20001004.xml 10.24388/ k20001004 R. S. Timonen; E. Ratajczak; D. Gutman; A. F. Wagner, The Journal of Physical Chemistry 1987, 91, (20), 5325-5332, Table I, M = He Rate coefficient determination - LP HCO + M = CO + H + M  
k20001005.xml 10.24388/ k20001005 R. S. Timonen; E. Ratajczak; D. Gutman; A. F. Wagner, The Journal of Physical Chemistry 1987, 91, (20), 5325-5332, Table I, M = N2 Rate coefficient determination - LP HCO + M = CO + H + M  
k20001006.xml 10.24388/ k20001006 R. S. Timonen; E. Ratajczak; D. Gutman; A. F. Wagner, The Journal of Physical Chemistry 1987, 91, (20), 5325-5332, Table I, M = Ar Rate coefficient determination - LP HCO + M = CO + H + M  
k20001007.xml 10.24388/ k20001007 G. Friedrichs; J. T. Herbon; D. F. Davidson; R. K. Hanson, Physical Chemistry Chemical Physics 2002, 4, (23), 5778-5788, Fig. 10, open circle and open diamond; not all data points could be digitized Rate coefficient determination - LP HCO + M = CO + H + M  
k20001008.xml 10.24388/ k20001008 H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 1 Rate coefficient determination - HCO + M = CO + H + M  
k20001009.xml 10.24388/ k20001009 H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 2 Rate coefficient determination - HCO + M = CO + H + M  
k20001010.xml 10.24388/ k20001010 H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 3 Rate coefficient determination - HCO + M = CO + H + M  
k20001011.xml 10.24388/ k20001011 H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 4 Rate coefficient determination - HCO + M = CO + H + M  
k20001012.xml 10.24388/ k20001012 H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 5 Rate coefficient determination - HCO + M = CO + H + M  
k20001013.xml 10.24388/ k20001013 H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 6 Rate coefficient determination - HCO + M = CO + H + M  
k20001014.xml 10.24388/ k20001014 L. N. Krasnoperov; E. N. Chesnokov; H. Stark; A. R. Ravishankara, The Journal of Physical Chemistry A 2004, 108, (52), 11526-11536, Table 1, low pressure data points only Rate coefficient determination - HCO + M = CO + H + M  
k20001015.xml 10.24388/ k20001015 L. N. Krasnoperov; E. N. Chesnokov; H. Stark; A. R. Ravishankara, The Journal of Physical Chemistry A 2004, 108, (52), 11526-11536, Table 1, high pressure data points only Rate coefficient determination - HCO + M = CO + H + M  
k20003001.xml 10.24388/ k20003001 J. Herzler, J.A. Manion, W. Tsang, J. Phys. Chem. A, 101 (1997), 6600-5508, Fig. 7 Rate coefficient determination - C2H5OH(+M)=PRODUCTS  
k20003002.xml 10.24388/ k20003002 J. Park, R. Chen, J. Chen, M.C. Lin, Experimental and Computational Studies of the Unimolecular Decomposition of Ethanol, 2001 Eastern States Section Fall Technical Meeting, Dec. 4-7, 2001. Data taken from: J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Fig. 4a, full circle Rate coefficient determination - HPC2H5OH(+M)=C2H4+H2O(+M)  
k20003003.xml 10.24388/ k20003003 J. Park, R. Chen, J. Chen, M.C. Lin, Experimental and Computational Studies of the Unimolecular Decomposition of Ethanol, 2001 Eastern States Section Fall Technical Meeting, Dec. 4-7, 2001. Data taken from: J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Fig. 4a, open circle Rate coefficient determination - HPC2H5OH(+M)=C2H4+H2O(+M)  
k20003004.xml 10.24388/ k20003004 J. Park, R. Chen, J. Chen, M.C. Lin, Experimental and Computational Studies of the Unimolecular Decomposition of Ethanol, 2001 Eastern States Section Fall Technical Meeting, Dec. 4-7, 2001. Data taken from: J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Fig. 4b, open circle Rate coefficient determination - HPC2H5OH(+M)=CH3+CH2OH(+M)  
k20003005.xml 10.24388/ k20003005 J. Li, A. Kazakov, F.L. Dryer, J. Phys. Chem. A, 108 (2004), 7671-7680, Fig. 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
k20003006.xml 10.24388/ k20003006 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 6 Torr Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
k20003007.xml 10.24388/ k20003007 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 11 Torr Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
k20003008.xml 10.24388/ k20003008 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 16 Torr Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
k20003009.xml 10.24388/ k20003009 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 31 Torr Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
k20003010.xml 10.24388/ k20003010 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 6 Torr Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
k20003011.xml 10.24388/ k20003011 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 11 Torr Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
k20003012.xml 10.24388/ k20003012 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 16 Torr Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
k20003013.xml 10.24388/ k20003013 R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 31 Torr Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
k20003014.xml 10.24388/ k20003014 C.-W. Wu, H. Matsui, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 115 (2011), 8086-8092, Table 1A Rate coefficient determination - C2H5OH(+M)=PRODUCTS  
k20003015.xml 10.24388/ k20003015 C.-W. Wu, H. Matsui, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 115 (2011), 8086-8092, Table 1B Rate coefficient determination - C2H5OH(+M)=PRODUCTS  
k20003016.xml 10.24388/ k20003016 C.-W. Wu, H. Matsui, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 115 (2011), 8086-8092, Table 1C Rate coefficient determination - C2H5OH(+M)=PRODUCTS  
k30003001.xml 10.24388/ k30003001 K.M. Bansal, G.R. Freeman, J. Amer. Chem. Soc. 90 (1968), 7183-7189, Table II. Rate coefficient determination - C2H5OH+CH3=CH3CHOH+CH4  
k30005001.xml 10.24388/ k30005001 N.K. Srinivasan, M.-C. Su, J.V. Michael, Phys. Chem. Chem. Phys. 9 (2007) 4155-4163, Table 4 Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005002.xml 10.24388/ k30005002 S.S. Vasu, Z. Hong, D.F. Davidson, R.K. Hanson, D.M. Golden, J. Phys. Chem. A 114 (2010), 11529-11537, Table 2 Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005003.xml 10.24388/ k30005003 D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 1 bar series Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005004.xml 10.24388/ k30005004 D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 15 bar series Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005005.xml 10.24388/ k30005005 D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 40 bar series Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005006.xml 10.24388/ k30005006 D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 139 bar series Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005008.xml 10.24388/ k30005008 R. Zellner, K. Lorenz, J. Phys. Chem. 88 (1984) 984-989, high-pressure limits extracted from page 987 Rate coefficient determination - C2H4+OH=PRODUCTS  
k30005009.xml 10.24388/ k30005009 R. Atkinson, R.A. Perry, J.N. Pitts Jr., J. Chem. Phys. 66 (1977) 1197-1201, Table 1, high pressure rate constants (least square average of data at p .ge. 225 Torr) Rate coefficient determination - C2H4+OH=PRODUCTS  
k40001002.xml 10.24388/ k40001002 N. Fujii; T. Kakuda; N. Takeishi; H. Miyama, The Journal of Physical Chemistry 1987, 91, (8), 2144-2148, Table II. Rate coefficient determination - LP CO+O(+M) = CO2(+M) N2O CO Ar He
k40001003.xml 10.24388/ k40001003 A. M. Dean; D. C. Steiner, The Journal of Chemical Physics 1977, 66, (2), 598-604, Table I. Rate coefficient determination - LP CO+O(+M) = CO2(+M) N2O CO Ar
k50001001.xml 10.24388/ k50001001 K. Thielen; P. Roth, Ber. Bunsenges. Phys. Chem 1983, 87, 920-925, Fig. 10, all shapes Rate coefficient determination - CO + O2 = CO2 + O  
k50002001.xml 10.24388/ k50002001 M. Brouard, M.T. Macpherson, M.J. Pilling, J.M. Tulloch, A.P. Williamson, Chem. Phys. Lett. 113 (1985), 413-418, Table 1 Rate coefficient determination - CH3+H(+M)=CH4(+M)  
k50002006.xml 10.24388/ k50002006 M. Brouard, M.T. Macpherson, M.J. Pilling, J. Phys. Chem. 93 (1989) 4047-4059, Table 1, 401 K series Rate coefficient determination - CH3+H(+M)=CH4(+M)  
k50002007.xml 10.24388/ k50002007 M. Brouard, M.T. Macpherson, M.J. Pilling, J. Phys. Chem. 93 (1989) 4047-4059, Table 1, 504 K series Rate coefficient determination - CH3+H(+M)=CH4(+M)  
k50002008.xml 10.24388/ k50002008 M. Brouard, M.T. Macpherson, M.J. Pilling, J. Phys. Chem. 93 (1989) 4047-4059, Table 1, 601 K series Rate coefficient determination - CH3+H(+M)=CH4(+M)  
k50002101.xml 10.24388/ k50002101 J.W. Sutherland, M.-C. Su, J.V. Michael, Int. J. Chem. Kinet. 33 (2001), 669-684, Table IV Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002102.xml 10.24388/ k50002102 T. Koike, M. Kudo, I. Maeda, H. Yamada, Int. J. Chem. Kinet. 32 (2000), 1-16, Fig. 3, open symbols Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002103.xml 10.24388/ k50002103 J.H. Kiefer, S.S. Kumaran, J. Phys. Chem 97 (1993), 414-420, Table I, Kr data Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002104.xml 10.24388/ k50002104 J.H. Kiefer, S.S. Kumaran, J. Phys. Chem 97 (1993), 414-420, Table I, Ar data Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002107.xml 10.24388/ k50002107 D.F. Davidson, M.D. Di Rosa, A.Y. Chang, R.K. Hanson, C.T. Bowman, Proc. Combust. Inst. 24 (1992), 589-596, Table II Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002108.xml 10.24388/ k50002108 P. Roth, Th. Just, Ber. Bunsenges. Phys. Chem. 79 (1975) 682-686, Fig. 3 Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002109.xml 10.24388/ k50002109 K. Tabayashi, S.H. Bauer, Combust. Flame 34 (1979), 63-83, Table 1 Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002110.xml 10.24388/ k50002110 W.M. Heffington, G.E. Parks, K.G.P. Sulzmann, S.S. Penner, Proc. Combust. Inst. 16 (1977) 997-1011, Fig. 3 Rate coefficient determination - LPCH4(+M)=CH3+H(+M)  
k50002111.xml 10.24388/ k50002111 C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 995 K series Rate coefficient determination - CH4(+M)=CH3+H(+M)  
k50002112.xml 10.24388/ k50002112 C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 1038 K series Rate coefficient determination - CH4(+M)=CH3+H(+M)  
k50002113.xml 10.24388/ k50002113 C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 1068 K series Rate coefficient determination - CH4(+M)=CH3+H(+M)  
k50002114.xml 10.24388/ k50002114 C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 1103 K series Rate coefficient determination - CH4(+M)=CH3+H(+M)  
k70002201.xml 10.24388/ k70002201 Z. Hong, D.F. Davidson, K.-Y. Lam, R.K. Hanson, Combust. Flame 159 (2012), 3007-3013, Table 1, k1 Rate coefficient determination - CH3+HO2=CH3O+OH  
k70002202.xml 10.24388/ k70002202 J.J. Scire Jr., R.A. Yetter, F.L. Dryer, Int. J. Chem. Kinet. 33 (2001), 75-100, Table II, k1 Rate coefficient determination - CH3+HO2=CH3O+OH  
k70002301.xml 10.24388/ k70002301 C. Yan, L.N. Krasnoperov, Reactions of CH3 radicals with HO2, International Conference on Chemical Kinetics 2015, Ghent, Belgium, Lecture O21, Fig. 1, digitized Rate coefficient determination - CH3+HO2=PRODUCTS  
t10003001.xml 10.24388/ t10003001 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, alpha-site abstraction branch Rate coefficient determination - C2H5OH+OH=CH3CHOH+H2O  
t10003002.xml 10.24388/ t10003002 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, beta-site abstraction branch Rate coefficient determination - C2H5OH+OH=C2H4OH+H2O  
t10003003.xml 10.24388/ t10003003 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, OH-site abstraction branch Rate coefficient determination - C2H5OH+OH=CH3CH2O+H2O  
t10003004.xml 10.24388/ t10003004 J. Zheng, D.G. Truhlar, Faraday Discuss. (2012), 157, 59-88, alpha-site abstraction branch Rate coefficient determination - C2H5OH+OH=CH3CHOH+H2O  
t10003005.xml 10.24388/ t10003005 J. Zheng, D.G. Truhlar, Faraday Discuss. (2012), 157, 59-88, beta-site abstraction branch Rate coefficient determination - C2H5OH+OH=C2H4OH+H2O  
t10003006.xml 10.24388/ t10003006 J. Zheng, D.G. Truhlar, Faraday Discuss. (2012), 157, 59-88, OH-site abstraction branch Rate coefficient determination - C2H5OH+OH=CH3CH2O+H2O  
t10003007.xml 10.24388/ t10003007 S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166, alpha-site abstraction branch Rate coefficient determination - C2H5OH+OH=CH3CHOH+H2O  
t10003008.xml 10.24388/ t10003008 S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166, beta-site abstraction branch Rate coefficient determination - C2H5OH+OH=C2H4OH+H2O  
t10003009.xml 10.24388/ t10003009 S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166, OH-site abstraction branch Rate coefficient determination - C2H5OH+OH=CH3CH2O+H2O  
t10005001.xml 10.24388/ t10005001 R.S. Zhu, J. Park, M.C. Lin, Chem. Phys. Lett. 408 (2005), 25-30, digitized from Fig. 4, k3 Rate coefficient determination - C2H4+OH=C2H3+H2O  
t10005002.xml 10.24388/ t10005002 G.X. Liu, Y.H. Ding, Z.S. Li, Q. Fu, X.R. Huang, C.C. Sun, A.C. Tang, Phys. Chem. Chem. Phys. 4 (2002), 1021-1027, Table 3, CVT/SCT Rate coefficient determination - C2H4+OH=C2H3+H2O  
t10005003.xml 10.24388/ t10005003 S.S. Vasu, Z. Hong, D.F. Davidson, R.K. Hanson, D.M. Golden, J. Phys. Chem. A 114 (2010), 11529-11537, Eq. 2 Rate coefficient determination - C2H4+OH=C2H3+H2O  
t10005004.xml 10.24388/ t10005004 J.P. Senosiain, S.J. Klippenstein, J.A. Miller, J. Phys. Chem. A 110 (2006), 6960-6970, Table 6, H2O+CHCH2 Rate coefficient determination - C2H4+OH=C2H3+H2O  
t13002001.xml 10.24388/ t13002001 A.W. Jasper, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 111 (2007) 3932-3950, Table 3 Rate coefficient determination - CH3+OH=S-CH2+H2O  
t20003001.xml 10.24388/ t20003001 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003002.xml 10.24388/ t20003002 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003003.xml 10.24388/ t20003003 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003004.xml 10.24388/ t20003004 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003005.xml 10.24388/ t20003005 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003006.xml 10.24388/ t20003006 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003007.xml 10.24388/ t20003007 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003008.xml 10.24388/ t20003008 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003009.xml 10.24388/ t20003009 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003010.xml 10.24388/ t20003010 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003011.xml 10.24388/ t20003011 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003012.xml 10.24388/ t20003012 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003013.xml 10.24388/ t20003013 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003014.xml 10.24388/ t20003014 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003015.xml 10.24388/ t20003015 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003016.xml 10.24388/ t20003016 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003017.xml 10.24388/ t20003017 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003018.xml 10.24388/ t20003018 R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003019.xml 10.24388/ t20003019 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003020.xml 10.24388/ t20003020 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003021.xml 10.24388/ t20003021 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1 Rate coefficient determination - C2H5OH(+M)=C2H4+H2O(+M)  
t20003022.xml 10.24388/ t20003022 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1 Rate coefficient determination - HPC2H5OH(+M)=C2H4+H2O(+M)  
t20003023.xml 10.24388/ t20003023 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003024.xml 10.24388/ t20003024 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003025.xml 10.24388/ t20003025 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - C2H5OH(+M)=CH3+CH2OH(+M)  
t20003026.xml 10.24388/ t20003026 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - HPC2H5OH(+M)=CH3+CH2OH(+M)  
t20003027.xml 10.24388/ t20003027 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003028.xml 10.24388/ t20003028 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003029.xml 10.24388/ t20003029 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - C2H5OH(+M)=C2H5+OH(+M)  
t20003030.xml 10.24388/ t20003030 J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2 Rate coefficient determination - HPC2H5OH(+M)=C2H5+OH(+M)  
t30003001.xml 10.24388/ t30003001 X.F. Xu, J. Park, M.C. Lin, J. Chem. Phys. 120 (2004), 6593-6599, Table II, k1a Rate coefficient determination - C2H5OH+CH3=CH3CHOH+CH4  
t30003002.xml 10.24388/ t30003002 X.F. Xu, J. Park, M.C. Lin, J. Chem. Phys. 120 (2004), 6593-6599, Table II, k2a Rate coefficient determination - C2H5OH+CH3=CH3CH2O+CH4  
t30003003.xml 10.24388/ t30003003 X.F. Xu, J. Park, M.C. Lin, J. Chem. Phys. 120 (2004), 6593-6599, Table II, k3a Rate coefficient determination - C2H5OH+CH3=CH2CH2OH+CH4  
t50002001.xml 10.24388/ t50002001 J. Troe, V.G. Ushakov, J. Chem. Phys. 136 (2012) 214309, see text Rate coefficient determination - LPCH3+H(+M)=CH4(+M)  
t50002002.xml 10.24388/ t50002002 J. Troe, V.G. Ushakov, J. Chem. Phys. 136 (2012) 214309, see text Rate coefficient determination - LPCH3+H(+M)=CH4(+M)  
t50003001.xml 10.24388/ t50003001 R. Sivaramakrishnan, J.V. Michael, S.J. Klippenstein, J. Phys. Chem. A 144 (2010), 755-764, Table 5 Rate coefficient determination - CH3CHO+H=CH3CO+H2  
t60003001.xml 10.24388/ t60003001 J. Park, Y.F. Xu, M.C. Lin, J. Chem. Phys. 118 (2003), 9990-9996, Arrhenius expression found in conclusion Rate coefficient determination - C2H5OH+H=CH3CHOH+H2  
t70002201.xml 10.24388/ t70002201 A.W. Jasper, S.J. Klippenstein, L.B. Harding, Proc. Combust. Inst. 32 (2009), 279-286, see text Rate coefficient determination - CH3+HO2=CH3O+OH  
x00000065_p.xml 10.24388/ x00000065_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000066_p.xml 10.24388/ x00000066_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000067_p.xml 10.24388/ x00000067_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000068_p.xml 10.24388/ x00000068_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000069_p.xml 10.24388/ x00000069_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000070_p.xml 10.24388/ x00000070_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000071_p.xml 10.24388/ x00000071_p Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946. ignition delay measurement H2 O2 Ar
x00000185_p.xml 10.24388/ x00000185_p Taylor., S.C., Ph.D. thesis, University of Leeds, 1991. laminar burning velocity measurement H2 O2 N2
x00000356_p.xml 10.24388/ x00000356_p Cheng, R.K., Oppenheim, A.K., Combustion and Flame, 1984, (58) 125-139., Fig. 4., open triangle ignition delay measurement H2 O2 Ar
x00000357_p.xml 10.24388/ x00000357_p Cohen, A., Larsen, J., 1967, Report BRL 1386, technical report, original PrIMe file ignition delay measurement H2 O2 Ar
x00001001.xml 10.24388/ x00001001 P. Dagaut; F. Lecomte; J. Mieritz; P. Glarborg, International Journal of Chemical Kinetics 2003, 35, 564-575, Fig. 1a jet stirred reactor measurement H2 CO O2 N2
x00001002.xml 10.24388/ x00001002 P. Dagaut; F. Lecomte; J. Mieritz; P. Glarborg, International Journal of Chemical Kinetics 2003, 35, 564-575, Fig. 2a jet stirred reactor measurement H2 CO O2 N2
x00001003_x.xml 10.24388/ x00001003_x P. Dagaut; F. Lecomte; J. Mieritz; P. Glarborg, International Journal of Chemical Kinetics 2003, 35, 564-575, Fig. 3a jet stirred reactor measurement H2 CO O2 N2
x00003001.xml 10.24388/ x00003001 N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 9, C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003002.xml 10.24388/ x00003002 N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 8, C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003003.xml 10.24388/ x00003003 N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 6, C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003004.xml 10.24388/ x00003004 N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 7, C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003005_x.xml 10.24388/ x00003005_x N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 14, C2H2 and C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003006_x.xml 10.24388/ x00003006_x N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 13, C2H2 and C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003007_x.xml 10.24388/ x00003007_x N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 11, C2H2 and C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003008_x.xml 10.24388/ x00003008_x N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 12, C2H2 and C3H6 not taken jet stirred reactor measurement C2H5OH O2 N2
x00003009_x.xml 10.24388/ x00003009_x B. Aboussi, Ph.D. Dissertation, Orleans, 1991. data from: P. Dagaut, J.C. Boettner, M. Cathonnet, J. Chim. Phys. 89 (1992), 867-884, Fig. 2a (phi=1) jet stirred reactor measurement C2H5OH O2 N2
x00003010_x.xml 10.24388/ x00003010_x B. Aboussi, Ph.D. Dissertation, Orleans, 1991. data from: P. Dagaut, J.C. Boettner, M. Cathonnet, J. Chim. Phys. 89 (1992), 867-884, Fig. 2b (phi=2) jet stirred reactor measurement C2H5OH O2 N2
x10000001.xml 10.24388/ x10000001 Skinner G.B., Ringrose G.H., Journal of Chemical Physics, (42) 2190-2192., 1965, Table I. ignition delay measurement H2 O2 Ar
x10000002.xml 10.24388/ x10000002 Schott G.L., Kinsey J.L., Journal of Chemical Physics, (29), 1177-1182., 1958, Fig. 3., open triangle ignition delay measurement H2 O2 Ar
x10000005.xml 10.24388/ x10000005 Slack M.W., Combustion and Flame, (28), 241-249., 1977, Fig. 2., full circle ignition delay measurement H2 O2 N2
x10000006.xml 10.24388/ x10000006 Fujimoto, S., Suzuki, M., Memoirs of the Defense Academy, Japan, 1967, (VII., 3), 1037-1046, Table 1. ignition delay measurement H2 O2 Ar
x10000007_x.xml 10.24388/ x10000007_x Fujimoto, S., Suzuki, M., Memoirs of the Defense Academy, Japan, 1967, (VII., 3), 1037-1046, Table 2. ignition delay measurement H2 O2 Ar
x10000008.xml 10.24388/ x10000008 Petersen, E.L., Kalitan, D.M., Rickard,M.J.A., Proceedings of the Third Joint Meeting of the U.S. Sections of The Combustion Institute, 2003, 1-6., Fig. 2., full square ignition delay measurement H2 O2 Ar
x10000016.xml 10.24388/ x10000016 Petersen, E.L., Kalitan, D.M., Rickard,M.J.A., Proceedings of the Third Joint Meeting of the U.S. Sections of The Combustion Institute, 2003, 1-6., Fig. 4., full triangle ignition delay measurement H2 O2 Ar
x10000017_x.xml 10.24388/ x10000017_x Petersen, E.L., Kalitan, D.M., Rickard,M.J.A., Proceedings of the Third Joint Meeting of the U.S. Sections of The Combustion Institute, 2003, 1-6., Fig. 3., full circle ignition delay measurement H2 O2 Ar
x10000019.xml 10.24388/ x10000019 Cheng, R.K., Oppenheim, A.K., Combustion and Flame, 1984, (58) 125-139., Fig. 4., open diamond ignition delay measurement H2 O2 Ar
x10000020.xml 10.24388/ x10000020 Bhaskaran K.A., Gupta M.C., Just, T.H., Combustion and Flame, 1973, (21), (1), 45-48., Fig. 4., open circle ignition delay measurement H2 O2 N2
x10000021_x.xml 10.24388/ x10000021_x Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 8., full square ignition delay measurement H2 O2 N2 H2O
x10000022.xml 10.24388/ x10000022 Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 6., full circle ignition delay measurement H2 O2 N2
x10000023.xml 10.24388/ x10000023 Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 7., full triangle ignition delay measurement H2 O2 H2O N2
x10000024_x.xml 10.24388/ x10000024_x Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 9., full diamond ignition delay measurement H2 O2 N2 H2O
x10000025.xml 10.24388/ x10000025 Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 10., open circle ignition delay measurement H2 O2 N2 H2O
x10000026.xml 10.24388/ x10000026 Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106.,Fig. 10., crossed X ignition delay measurement H2 O2 N2 H2O
x10000027_x.xml 10.24388/ x10000027_x Asaba T., Gardiner W.C.Jr., Stubbeman R.F., Proceedings of the Combustion Institute, 1965, (10), 295-302., Fig. 6., full circle ignition delay measurement H2 O2 Ar
x10000028.xml 10.24388/ x10000028 Asaba T., Gardiner W.C.Jr., Stubbeman R.F., Proceedings of the Combustion Institute, 1965, (10), 295-302., Fig. 6., open circle ignition delay measurement H2 O2 Ar
x10000029_x.xml 10.24388/ x10000029_x Asaba T., Gardiner W.C.Jr., Stubbeman R.F., Proceedings of the Combustion Institute, 1965, (10), 295-302., Fig. 6., full rectangle ignition delay measurement H2 O2 Ar
x10000030_x.xml 10.24388/ x10000030_x Zhang, Y., Huang, Z., Wei, L., Zhang, J., Law, C.K., Combustion and Flame, (159), 918-931, 2012, Fig. 9., full square ignition delay measurement H2 O2 Ar
x10000031.xml 10.24388/ x10000031 Zhang, Y., Huang, Z., Wei, L., Zhang, J., Law, C.K., Combustion and Flame, (159), 918-931, 2012, Fig. 9., full circle ignition delay measurement H2 O2 Ar
x10000032.xml 10.24388/ x10000032 Zhang, Y., Huang, Z., Wei, L., Zhang, J., Law, C.K., Combustion and Flame, (159), 918-931, 2012, Fig. 9., full triangle ignition delay measurement H2 O2 Ar
x10001001.xml 10.24388/ x10001001 E. L. Petersen; D. M. Kalitan; A. B. Barrett; S. C. Reehal; J. D. Mertens; D. J. Beerer; R. L. Hack; V. G. McDonell, Combustion and Flame 2007, 149, (1-2), 244-247, Table 1, top ignition delay measurement H2 CO CO2 O2 N2
x10001009.xml 10.24388/ x10001009 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:5, 16 bar series ignition delay measurement H2 O2 Ar
x10001010.xml 10.24388/ x10001010 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:5, 4 bar series ignition delay measurement H2 O2 Ar
x10001011.xml 10.24388/ x10001011 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:5, 1 bar series ignition delay measurement H2 O2 Ar
x10001012_x.xml 10.24388/ x10001012_x C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:1, 16 bar series ignition delay measurement H2 O2 Ar
x10001013.xml 10.24388/ x10001013 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:1, 4 bar series ignition delay measurement H2 O2 Ar
x10001014.xml 10.24388/ x10001014 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:1, 1 bar series ignition delay measurement H2 O2 Ar
x10001015.xml 10.24388/ x10001015 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 4.0, dilution 1:5, 16 bar series ignition delay measurement H2 O2 Ar
x10001016.xml 10.24388/ x10001016 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 4.0, dilution 1:5, 4 bar series ignition delay measurement H2 O2 Ar
x10001017.xml 10.24388/ x10001017 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 4.0, dilution 1:5, 1 bar series ignition delay measurement H2 O2 Ar
x10001018.xml 10.24388/ x10001018 C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.5, dilution 1:5, 16 bar series ignition delay measurement H2 O2 N2
x10001019_x.xml 10.24388/ x10001019_x C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.5, dilution 1:5, 4 bar series ignition delay measurement H2 O2 N2
x10001020.xml 10.24388/ x10001020 Naumann, C., Herzler, J., Griebel, P., Curran, H., Keromnes H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.5, dilution 1:5, 1 bar series ignition delay measurement H2 O2 N2
x10001021_x.xml 10.24388/ x10001021_x C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 5/95, 16 bar series ignition delay measurement H2 CO O2 Ar
x10001022.xml 10.24388/ x10001022 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 5/95, 4 bar series ignition delay measurement H2 CO O2 Ar
x10001023.xml 10.24388/ x10001023 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 5/95, 1 bar series ignition delay measurement H2 CO O2 Ar
x10001024_x.xml 10.24388/ x10001024_x C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 50/50, 16 bar series ignition delay measurement H2 CO O2 Ar
x10001025.xml 10.24388/ x10001025 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 50/50, 4 bar series ignition delay measurement H2 CO O2 Ar
x10001026.xml 10.24388/ x10001026 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 50/50, 1 bar series ignition delay measurement H2 CO O2 Ar
x10001027_x.xml 10.24388/ x10001027_x C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 16 bar series ignition delay measurement H2 CO O2 Ar
x10001028.xml 10.24388/ x10001028 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 4 bar series ignition delay measurement H2 CO O2 Ar
x10001029.xml 10.24388/ x10001029 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 1 bar series ignition delay measurement H2 CO O2 Ar
x10001030.xml 10.24388/ x10001030 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 16 bar series ignition delay measurement H2 CO O2 Ar
x10001031.xml 10.24388/ x10001031 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 4 bar series ignition delay measurement H2 CO O2 Ar
x10001032.xml 10.24388/ x10001032 C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 1 bar series ignition delay measurement H2 CO O2 Ar
x10001033.xml 10.24388/ x10001033 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 80/20 (mixture 1), low pressure series ignition delay measurement H2 CO O2 N2
x10001034.xml 10.24388/ x10001034 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 60/40 (mixture 2), low pressure series ignition delay measurement H2 CO O2 N2
x10001035.xml 10.24388/ x10001035 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 40/60 (mixture 3), low pressure series ignition delay measurement H2 CO O2 N2
x10001036.xml 10.24388/ x10001036 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 20/80 (mixture 4), low pressure series ignition delay measurement H2 CO O2 N2
x10001037.xml 10.24388/ x10001037 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 20/80 (mixture 4), mid pressure series ignition delay measurement H2 CO O2 N2
x10001038.xml 10.24388/ x10001038 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 20/80 (mixture 4), high pressure series ignition delay measurement H2 CO O2 N2
x10001039.xml 10.24388/ x10001039 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 10/90 (mixture 5), low pressure series ignition delay measurement H2 CO O2 N2
x10001040.xml 10.24388/ x10001040 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 10/90 (mixture 5), low pressure series ignition delay measurement H2 CO O2 N2
x10001041.xml 10.24388/ x10001041 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 10/90 (mixture 5), high pressure series ignition delay measurement H2 CO O2 N2
x10001042.xml 10.24388/ x10001042 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 5/95 (mixture 6), low pressure series ignition delay measurement H2 CO O2 N2
x10001043.xml 10.24388/ x10001043 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 5/95 (mixture 6), mid pressure series ignition delay measurement H2 CO O2 N2
x10001044.xml 10.24388/ x10001044 D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 5/95 (mixture 6), high pressure series ignition delay measurement H2 CO O2 N2
x10001049.xml 10.24388/ x10001049 A. M. Dean; D. C. Steiner; E. E. Wang, Combustion and Flame 1978, 32, (0), 73-83, Table 2, mixture C, tau_1 definition ignition delay measurement H2 CO O2 Ar
x10001050.xml 10.24388/ x10001050 A. M. Dean; D. C. Steiner; E. E. Wang, Combustion and Flame 1978, 32, (0), 73-83, Table 2, mixture C, tau_2 definition ignition delay measurement H2 CO O2 Ar
x10001051.xml 10.24388/ x10001051 A. M. Dean; D. C. Steiner; E. E. Wang, Combustion and Flame 1978, 32, (0), 73-83, Table 2, mixture D, tau_1 definition ignition delay measurement H2 CO O2 Ar
x10001052.xml 10.24388/ x10001052 A. M. Dean; D. C. Steiner; E. E. Wang, Combustion and Flame 1978, 32, (0), 73-83, Table 2, mixture D, tau_2 definition ignition delay measurement H2 CO O2 Ar
x10001053.xml 10.24388/ x10001053 J. Herzler; C. Naumann, Combustion Science and Technology 2008, 180, (10-11), 2015-2028, Table 2, H2/CO/O2/Ar, Phi = 0.5, dilution 1:2, H2 /CO = 5/95, 16 bar series ignition delay measurement CO H2 O2 Ar
x10001054.xml 10.24388/ x10001054 J. Herzler; C. Naumann, Combustion Science and Technology 2008, 180, (10-11), 2015-2028, Table 2, H2/CO/O2/Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 16 bar series ignition delay measurement CO H2 O2 Ar
x10001055.xml 10.24388/ x10001055 J. Herzler; C. Naumann, Combustion Science and Technology 2008, 180, (10-11), 2015-2028, Table 2, H2/CO/O2/Ar, Phi = 0.5, dilution 1:10, H2 /CO = 5/95, 16 bar series ignition delay measurement CO H2 O2 Ar
x10001056.xml 10.24388/ x10001056 J. Herzler; C. Naumann, Combustion Science and Technology 2008, 180, (10-11), 2015-2028, Table 2, H2/CO/O2/Ar, Phi = 0.5, dilution 1:2, H2 /CO = 50/50, 16 bar series ignition delay measurement CO H2 O2 Ar
x10001057.xml 10.24388/ x10001057 J. Herzler; C. Naumann, Combustion Science and Technology 2008, 180, (10-11), 2015-2028, Table 2, H2/CO/O2/Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 16 bar series ignition delay measurement CO H2 O2 Ar
x10001058.xml 10.24388/ x10001058 J. Herzler; C. Naumann, Combustion Science and Technology 2008, 180, (10-11), 2015-2028, Table 2, H2/CO/O2/Ar, Phi = 0.5, dilution 1:10, H2 /CO = 50/50, 16 bar series ignition delay measurement CO H2 O2 Ar
x10001059.xml 10.24388/ x10001059 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A5, H2/CO/O2/Ar = 0.008/0.002/0.01/0.98, low pressure series ignition delay measurement H2 CO O2 Ar
x10001060.xml 10.24388/ x10001060 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Ksromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A5, H2/CO/O2/Ar = 0.008/0.002/0.01/0.98, mid pressure series ignition delay measurement H2 CO O2 Ar
x10001061.xml 10.24388/ x10001061 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A5, H2/CO/O2/Ar = 0.008/0.002/0.01/0.98, high pressure series ignition delay measurement H2 CO O2 Ar
x10001062.xml 10.24388/ x10001062 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A6, H2/CO/O2/Ar = 0.005/0.005/0.01/0.98, low pressure series ignition delay measurement H2 CO O2 Ar
x10001063.xml 10.24388/ x10001063 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A6, H2/CO/O2/Ar = 0.005/0.005/0.01/0.98, mid pressure series ignition delay measurement H2 CO O2 Ar
x10001064.xml 10.24388/ x10001064 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A6, H2/CO/O2/Ar = 0.005/0.005/0.01/0.98, high pressure series ignition delay measurement H2 CO O2 Ar
x10001065.xml 10.24388/ x10001065 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A7, H2/CO/O2/Ar = 0.004/0.006/0.01/0.98, low pressure series ignition delay measurement H2 CO O2 Ar
x10001066.xml 10.24388/ x10001066 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A7, H2/CO/O2/Ar = 0.004/0.006/0.01/0.98, mid pressure series ignition delay measurement H2 CO O2 Ar
x10001067.xml 10.24388/ x10001067 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A7, H2/CO/O2/Ar = 0.004/0.006/0.01/0.98, high pressure series ignition delay measurement H2 CO O2 Ar
x10001068.xml 10.24388/ x10001068 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A8, H2/CO/O2/Ar = 0.002/0.008/0.01/0.98, low pressure series ignition delay measurement H2 CO O2 Ar
x10001069.xml 10.24388/ x10001069 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A8, H2/CO/O2/Ar = 0.002/0.008/0.01/0.98, mid pressure series ignition delay measurement H2 CO O2 Ar
x10001070.xml 10.24388/ x10001070 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A8, H2/CO/O2/Ar = 0.002/0.008/0.01/0.98, high pressure series ignition delay measurement H2 CO O2 Ar
x10001071.xml 10.24388/ x10001071 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A9, H2/CO/O2/Ar = 0.001/0.009/0.01/0.98, low pressure series ignition delay measurement H2 CO O2 Ar
x10001072.xml 10.24388/ x10001072 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A9, H2/CO/O2/Ar = 0.001/0.009/0.01/0.98, mid pressure series ignition delay measurement H2 CO O2 Ar
x10001073.xml 10.24388/ x10001073 M. C. Krejci; O. Mathieu; A. J. Vissotski; S. Ravi; T. G. Sikes; E. L. Petersen; A. Keromnes; W. K. Metcalfe; H. J. Curran, Proceedings of ASME Turbo Expo 2012-GT2012, June 11-15, Copenhagen, Denmark 2012, Paper GT2012-69290, Table A9, H2/CO/O2/Ar = 0.001/0.009/0.01/0.98, high pressure series ignition delay measurement H2 CO O2 Ar
x10001074.xml 10.24388/ x10001074 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH70 (mixture 1), 0.2 MPa series ignition delay measurement H2 CO O2 Ar
x10001075.xml 10.24388/ x10001075 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH70 (mixture 1), 1 MPa series ignition delay measurement H2 CO O2 Ar
x10001076.xml 10.24388/ x10001076 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH70 (mixture 1), 2 MPa series ignition delay measurement H2 CO O2 Ar
x10001077.xml 10.24388/ x10001077 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH33 (mixture 2), 0.2 MPa series ignition delay measurement H2 CO O2 Ar
x10001078.xml 10.24388/ x10001078 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH33 (mixture 2), 1 MPa series ignition delay measurement H2 CO O2 Ar
x10001079.xml 10.24388/ x10001079 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH33 (mixture 2), 2 MPa series ignition delay measurement H2 CO O2 Ar
x10001080.xml 10.24388/ x10001080 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH50C30 (mixture 3), 0.2 MPa series ignition delay measurement H2 CO O2 CO2 Ar
x10001081.xml 10.24388/ x10001081 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH50C30 (mixture 3), 1 MPa series ignition delay measurement H2 CO O2 CO2 Ar
x10001082.xml 10.24388/ x10001082 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH50C30 (mixture 3), 2 MPa series ignition delay measurement H2 CO O2 CO2 Ar
x10001083.xml 10.24388/ x10001083 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH26N58 (mixture 4), 0.2 MPa series ignition delay measurement H2 CO O2 N2 Ar
x10001084.xml 10.24388/ x10001084 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH26N58 (mixture 4), 1 MPa series ignition delay measurement H2 CO O2 N2 Ar
x10001085.xml 10.24388/ x10001085 L. D. Thi, Y. Zhang, J. Fu, Z. Huang, Y. Zhang: Study on Ignition Delay of Multi-Component Syngas Using Shock Tube, The Canadian Journal of Chemical Engineering, 2013, in press, Suppl. Mat. Table 2, SH26N58 (mixture 4), 2 MPa series ignition delay measurement H2 CO O2 N2 Ar
x10003001.xml 10.24388/ x10003001 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy Fuels 24 (2010), 5834-5843, DOI:10.1021/ef1009692. Supp. Inf., Table 9. Mixture 2 (phi=0.5, D=15) ignition delay measurement C2H5OH O2 Ar
x10003002.xml 10.24388/ x10003002 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy Fuels 24 (2010), 5834-5843, DOI:10.1021/ef1009692. Supp. Inf., Table 10. Mixture 1 (phi=1, D=10) ignition delay measurement C2H5OH O2 Ar
x10003003.xml 10.24388/ x10003003 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy Fuels 24 (2010), 5834-5843, DOI:10.1021/ef1009692. Supp. Inf., Table 11. Low p series. Mixture 4 (phi=1, D=20) ignition delay measurement C2H5OH O2 Ar
x10003004.xml 10.24388/ x10003004 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy Fuels 24 (2010), 5834-5843, DOI:10.1021/ef1009692. Supp. Inf., Table 11. High p series. Mixture 4 (phi=1, D=20) ignition delay measurement C2H5OH O2 Ar
x10003005.xml 10.24388/ x10003005 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy Fuels 24 (2010), 5834-5843, DOI:10.1021/ef1009692. Supp. Inf., Table 12. Mixture 3 (phi=2, D=15) ignition delay measurement C2H5OH O2 Ar
x10003006.xml 10.24388/ x10003006 L.R. Cancino, M. Fikri, A.A.M. Oliveira, C. Schulz, Energy Fuels 24 (2010), 2830-2840, DOI:10.1021/ef100076. Table 2, phi=1/10 bar series ignition delay measurement C2H5OH O2 N2
x10003007.xml 10.24388/ x10003007 L.R. Cancino, M. Fikri, A.A.M. Oliveira, C. Schulz, Energy Fuels 24 (2010), 2830-2840, DOI:10.1021/ef100076. Table 2, phi=1/30 bar series ignition delay measurement C2H5OH O2 N2
x10003008.xml 10.24388/ x10003008 L.R. Cancino, M. Fikri, A.A.M. Oliveira, C. Schulz, Energy Fuels 24 (2010), 2830-2840, DOI:10.1021/ef100076. Table 2, phi=1/50 bar series ignition delay measurement C2H5OH O2 N2
x10003009.xml 10.24388/ x10003009 L.R. Cancino, M. Fikri, A.A.M. Oliveira, C. Schulz, Energy Fuels 24 (2010), 2830-2840, DOI:10.1021/ef100076. Table 2, phi=0.3/30 bar series ignition delay measurement C2H5OH O2 N2
x10003010_x.xml 10.24388/ x10003010_x D.F. Cooke, M.G. Dodson, A. Williams, Combust. Flame (16) 1971, 233-236. Fig. 2, dotted circle, CO2* emission ignition delay measurement C2H5OH O2 Ar
x10003011_x.xml 10.24388/ x10003011_x D.F. Cooke, M.G. Dodson, A. Williams, Combust. Flame (16) 1971, 233-236. Fig. 2, dotted triangle, CH* emission ignition delay measurement C2H5OH O2 Ar
x10003012_x.xml 10.24388/ x10003012_x D.F. Cooke, M.G. Dodson, A. Williams, Combust. Flame (16) 1971, 233-236. Fig. 2, dotted square, OH* emission ignition delay measurement C2H5OH O2 Ar
x10003022.xml 10.24388/ x10003022 C. Lee, S. Vranckx, K.A. Heufer, S.V. Khomik, Y. Uygun, H. Olivier, R.X. Fernandes, On the Chemical Kinetics of Ethanol Oxidation: Shock Tube, Rapid Compression Machine and Detailed Modeling Study. Z. Phys. Chem. 2012, 226, 1-27. DOI 10.1524/zpch.2012.0185, Table 1 ignition delay measurement C2H5OH O2 N2
x10003023.xml 10.24388/ x10003023 K.A. Heufer, H. Olivier: Determination of ignition delay times of different hydrocarbons in a new high pressure shock tube. Shock Waves, 2010, 20, 307-316, Fig. 12, green square, PRE-IGNITION DATA (T .lt. 900 K) from: Heufer, K.A., Olivier, H., Vranckx, S., Lee, C., Fernandes, R.X.: Experimental study of the high-pressure ignition of alcohol based biofuels. ECM 2011 Cardiff ignition delay measurement C2H5OH O2 N2
x10003024.xml 10.24388/ x10003024 K.A. Heufer, H. Olivier: Determination of ignition delay times of different hydrocarbons in a new high pressure shock tube. Shock Waves, 2010, 20, 307-316, Fig. 12, red triangle, PRE-IGNITION DATA (T .lt. 900 K) from: Heufer, K.A., Olivier, H., Vranckx, S., Lee, C., Fernandes, R.X.: Experimental study of the high-pressure ignition of alcohol based biofuels. ECM 2011 Cardiff ignition delay measurement C2H5OH O2 N2
x10003025.xml 10.24388/ x10003025 K.A. Heufer, H. Olivier: Determination of ignition delay times of different hydrocarbons in a new high pressure shock tube. Shock Waves, 2010, 20, 307-316, Fig. 12, purple diamond, PRE-IGNITION DATA (T .lt. 900 K) from: Heufer, K.A., Olivier, H., Vranckx, S., Lee, C., Fernandes, R.X.: Experimental study of the high-pressure ignition of alcohol based biofuels. ECM 2011 Cardiff ignition delay measurement C2H5OH O2 N2
x10003026.xml 10.24388/ x10003026 J. Herzler, C. Naumann: Ignition Delay Time Measurements for the Validation of Reaction Mechanisms for Different Alcohols. Proc. Europ. Combust Meeting 2013. Paper P3-8. Fig. 3, blue square ignition delay measurement C2H5OH O2 Ar
x10003027.xml 10.24388/ x10003027 J. Herzler, C. Naumann: Ignition Delay Time Measurements for the Validation of Reaction Mechanisms for Different Alcohols. Proc. Europ. Combust Meeting 2013. Paper P3-8. Fig. 3, red triangle, VTIM calculated at mean temperature (1282.5 K) was used ignition delay measurement C2H5OH O2 Ar
x10003028.xml 10.24388/ x10003028 J. Herzler, C. Naumann: Ignition Delay Time Measurements for the Validation of Reaction Mechanisms for Different Alcohols. Proc. Europ. Combust Meeting 2013. Paper P3-8. Fig. 3, black circle, VTIM calculated at mean temperature (1220.5 K) was used ignition delay measurement C2H5OH O2 Ar
x10003029.xml 10.24388/ x10003029 K. Natarajan, K.A. Bhaskaran, Thirteenth International Symposium on Shock Waves, 1982, pp. 834-842. Data from: Saxena Williams 2007, Fig. 2, open circle ignition delay measurement C2H5OH O2 Ar
x10003030.xml 10.24388/ x10003030 K. Natarajan, K.A. Bhaskaran, Thirteenth International Symposium on Shock Waves, 1982, pp. 834-842. Data from: Saxena Williams 2007, Fig. 2, open triangle ignition delay measurement C2H5OH O2 Ar
x10003031.xml 10.24388/ x10003031 K. Natarajan, K.A. Bhaskaran, Thirteenth International Symposium on Shock Waves, 1982, pp. 834-842. Data from: Saxena Williams 2007, Fig. 2, open square ignition delay measurement C2H5OH O2 Ar
x10003032.xml 10.24388/ x10003032 K. Natarajan, K.A. Bhaskaran, Thirteenth International Symposium on Shock Waves, 1982, pp. 834-842. Data from: Saxena Williams 2007, Fig. 2, full diamond ignition delay measurement C2H5OH O2 Ar
x10003033.xml 10.24388/ x10003033 K. Natarajan, K.A. Bhaskaran, Thirteenth International Symposium on Shock Waves, 1982, pp. 834-842. Data from: Saxena Williams 2007, correspondence with Priyank Saxena ignition delay measurement C2H5OH O2 Ar
x10003034.xml 10.24388/ x10003034 K. Natarajan, K.A. Bhaskaran, Thirteenth International Symposium on Shock Waves, 1982, pp. 834-842. Data from: Saxena Williams 2007, correspondence with Priyank Saxena ignition delay measurement C2H5OH O2 Ar
x10003035.xml 10.24388/ x10003035 K.A.Heufer, H. Olivier, S. Vranckx, C. Lee, R.X. Fernandes, Experimental study of the high-pressure ignition of alcohol based biofuels. Proc. 5th Europ. Combust. Meeting (2011), Cardiff, Fig. 1, top, blue reverse triangle ignition delay measurement C2H5OH O2 N2
x10003036.xml 10.24388/ x10003036 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400, Fig. 3, open blue circle ignition delay measurement C2H5OH O2 Ar Ne
x10003037.xml 10.24388/ x10003037 J. Herzler, M. Fikri, O. Welz, C. Schulz, Proc. 7th Europ. Combust. Meeting, 2015, P1-44, Fig. 6, full black square, CH4+5%C2H5OH autoignition, VTIM calculated at average temperature (1245 K) was used ignition delay measurement CH4 C2H5OH O2 N2
x10003038.xml 10.24388/ x10003038 M. Braun-Unkhoff, J. Dembowski, J. Herzler, J. Karle, C. Naumann, U. Riedel, J. Eng. Gas Turb Power 137 (2015), GTP-14-1640, mixture #225, 16 bar series, VTIM calculated at average temperature (1220.5 K) was used ignition delay measurement C2H5OH O2 Ar
x10003039.xml 10.24388/ x10003039 M. Braun-Unkhoff, J. Dembowski, J. Herzler, J. Karle, C. Naumann, U. Riedel, J. Eng. Gas Turb Power 137 (2015), GTP-14-1640, mixture #226, 4 bar series, VTIM calculated at average temperature (1282.5 K) was used ignition delay measurement C2H5OH O2 Ar
x10003040.xml 10.24388/ x10003040 M. Braun-Unkhoff, J. Dembowski, J. Herzler, J. Karle, C. Naumann, U. Riedel, J. Eng. Gas Turb Power 137 (2015), GTP-14-1640, mixture #225, 1 bar series, no VTIM was necessary ignition delay measurement C2H5OH O2 Ar
x10003041.xml 10.24388/ x10003041 I.N. Kosarev, S.V. Kindysheva, N.L. Aleksandrov, A.Yu. Starikovskiy, Combust. Flame (2015) 50-59, Fig. 7a, full square ignition delay measurement C2H5OH O2 Ar
x10003042.xml 10.24388/ x10003042 I.N. Kosarev, S.V. Kindysheva, N.L. Aleksandrov, A.Yu. Starikovskiy, Combust. Flame (2015) 50-59, Fig. 7b, full square ignition delay measurement C2H5OH O2 Ar
x20000001.xml 10.24388/ x20000001 Takahashi, F., Mizomoto, M., Ikai,S., Alternative Energy Sources III, 1983, (5), 447-457., Fig. 1., open circle laminar burning velocity measurement H2 O2 N2
x20000002.xml 10.24388/ x20000002 Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 3., full diamond laminar burning velocity measurement H2 O2 N2
x20000004_x.xml 10.24388/ x20000004_x Aung, K.T., Hassan, M.I., Faeth,G.M., Combustion and Flame, 1997, (109), 1-24., Fig. 6., full circle laminar burning velocity measurement H2 O2 N2
x20000005_x.xml 10.24388/ x20000005_x Iijima, T., Takeno,T., Combustion and Flame, 1986, (65), 35-43., Fig. 7., full circle laminar burning velocity measurement H2 O2 N2
x20000006_x.xml 10.24388/ x20000006_x Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 5a., open circle laminar burning velocity measurement H2 O2 He
x20000007.xml 10.24388/ x20000007 Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 5a., open square laminar burning velocity measurement H2 O2 He
x20000008.xml 10.24388/ x20000008 Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 5a., open triangle laminar burning velocity measurement H2 O2 He
x20000009.xml 10.24388/ x20000009 Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 5b., open circle laminar burning velocity measurement H2 O2 He
x20000010.xml 10.24388/ x20000010 Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 5b., open square laminar burning velocity measurement H2 O2 He
x20000011.xml 10.24388/ x20000011 Tse, S.D.,Zhu, D.L., Law, C.K., Proceedings of the Combustion Institute, 2000, (28), 1793-1800., Fig. 5b., open triangle laminar burning velocity measurement H2 O2 He
x20000014.xml 10.24388/ x20000014 Vagelopoulos, C.M., Egolfopoulos, F.N., Law,C.K., Proceedings of the Combustion Institute, 1994, (25), 1341-1347., Fig. 7., open square laminar burning velocity measurement H2 O2 N2
x20000022.xml 10.24388/ x20000022 Egolfopoulos, F.N., Law, C.K., Proceedings of the Combustion Institute, 1990, (23), 333-340., Fig. 1., open square laminar burning velocity measurement H2 O2 N2
x20000023.xml 10.24388/ x20000023 Hermanns, R.T.E., Konnov, A.A., Bastiaans, R.J.M., de Goey, L.P.H., Energy and Fuels, 2007, (21), (4), 1977-1981., Fig. 4., full circle laminar burning velocity measurement H2 O2 N2
x20000025.xml 10.24388/ x20000025 Lamoureux, N., Djebaili-Chaumeix, N., Paillard, C.E., Experimental Thermal and Fluid Science, 2003, (27), 385-393., Fig. 11., open circle laminar burning velocity measurement H2 O2 N2
x20000026_x.xml 10.24388/ x20000026_x Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 5. bottom, full circle laminar burning velocity measurement H2 O2 N2
x20000027.xml 10.24388/ x20000027 Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 5. center, full circle laminar burning velocity measurement H2 O2 N2
x20000028.xml 10.24388/ x20000028 Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 5. top, full circle laminar burning velocity measurement H2 O2 N2
x20000029.xml 10.24388/ x20000029 Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 6. bottom, full circle laminar burning velocity measurement H2 O2 N2
x20000030.xml 10.24388/ x20000030 Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 6. center, full circle laminar burning velocity measurement H2 O2 N2
x20000031.xml 10.24388/ x20000031 Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 6. top, full circle laminar burning velocity measurement H2 O2 N2
x20000032_x.xml 10.24388/ x20000032_x Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 7. bottom, full circle laminar burning velocity measurement H2 O2 N2
x20000033_x.xml 10.24388/ x20000033_x Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 7. lower center, full circle laminar burning velocity measurement H2 O2 N2
x20000034.xml 10.24388/ x20000034 Aung, K.T., Hassan, M.I., Faeth, G.M., Combustion and Flame, 1998, (112), 1-15., Fig. 7. upper center, full circle laminar burning velocity measurement H2 O2 N2
x20000035.xml 10.24388/ x20000035 Egolfopoulos, F.N., Law, C.K., Proceedings of the Combustion Institute, 1990, (23), 333-340., Fig. 3., open square laminar burning velocity measurement H2 O2 N2
x20000036.xml 10.24388/ x20000036 Egolfopoulos, F.N., Law, C.K., Proceedings of the Combustion Institute, 1990, (23), 333-340., Fig. 4., open square laminar burning velocity measurement H2 O2 N2
x20000037.xml 10.24388/ x20000037 Egolfopoulos, F.N., Law, C.K., Proceedings of the Combustion Institute, 1990, (23), 333-340., Fig. 5., open square laminar burning velocity measurement H2 O2 N2
x20000038.xml 10.24388/ x20000038 Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610., Fig. 5., full circle (H2/O2/N2) laminar burning velocity measurement H2 O2 N2
x20000039a.xml 10.24388/ x20000039a Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610, H2/O2/He, Table 3, phi=0.6, pressure varied laminar burning velocity measurement H2 O2 He
x20000039b.xml 10.24388/ x20000039b Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610, H2/O2/He, Table 3, pressure=1 atm, phi varied laminar burning velocity measurement H2 O2 He
x20000039c.xml 10.24388/ x20000039c Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610, H2/O2/He, Table 3, phi=4.5, pressure varied laminar burning velocity measurement H2 O2 He
x20000040a.xml 10.24388/ x20000040a Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610., Table 2, H2/O2/Ar, phi=0.6, pressure varried laminar burning velocity measurement H2 O2 Ar
x20000040b.xml 10.24388/ x20000040b Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610., Table 2, H2/O2/Ar, p=1atm, phi varried laminar burning velocity measurement H2 O2 Ar
x20000040c.xml 10.24388/ x20000040c Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610., Table 2, H2/O2/Ar, phi=4.5, pressure varried laminar burning velocity measurement H2 O2 Ar
x20000040d.xml 10.24388/ x20000040d Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610., Table 2, H2/O2/Ar, p=1atm, phi=4.5, O2/(O2+Ar) varied laminar burning velocity measurement H2 O2 Ar
x20000040e.xml 10.24388/ x20000040e Kwon, O.C., Faeth, G.M., Combustion and Flame, 2001, (124), 590-610., Table 2, H2/O2/Ar, p=1atm, phi=0.6, O2/(O2+Ar) varied laminar burning velocity measurement H2 O2 Ar
x20000041.xml 10.24388/ x20000041 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 4., full square laminar burning velocity measurement H2 O2 He
x20000042.xml 10.24388/ x20000042 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 6., full diamond laminar burning velocity measurement H2 O2 He
x20000043.xml 10.24388/ x20000043 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 6., full square laminar burning velocity measurement H2 O2 He
x20000044.xml 10.24388/ x20000044 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 6., full circle laminar burning velocity measurement H2 O2 He
x20000045.xml 10.24388/ x20000045 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 6., full triangle laminar burning velocity measurement H2 O2 He
x20000046.xml 10.24388/ x20000046 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 7., full diamond laminar burning velocity measurement H2 O2 Ar
x20000047.xml 10.24388/ x20000047 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 5., 7., full square laminar burning velocity measurement H2 O2 Ar
x20000048.xml 10.24388/ x20000048 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 7., full circle laminar burning velocity measurement H2 O2 Ar
x20000049.xml 10.24388/ x20000049 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 7., full triangle laminar burning velocity measurement H2 O2 Ar
x20000050.xml 10.24388/ x20000050 Tang, C., Huang, Z., Jin, C., He, J., Wang, J., International Journal of Hydrogen Energy, (33), 2008, 4906-4914, 2008, Fig. 8., full triangle laminar burning velocity measurement H2 O2 N2
x20000051_x.xml 10.24388/ x20000051_x Hu, E, Huang, Z, He, J., Jin, C., Zheng, J., International Journal of Hydrogen Energy, (34), 4876-4888, 2009, Fig. 10.b., open diamond laminar burning velocity measurement H2 O2 N2
x20000052_x.xml 10.24388/ x20000052_x Huang, Z., Zhang, Y., Zeng, K., Liu, B., Wang, Q., Jiang, D., Combustion and Flame, (146), 302-311, 2006, Fig. 9., full circle laminar burning velocity measurement H2 O2 N2
x20000053.xml 10.24388/ x20000053 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1., Fig. 3. full square laminar burning velocity measurement H2 O2 He
x20000054.xml 10.24388/ x20000054 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1. laminar burning velocity measurement H2 O2 He
x20000055.xml 10.24388/ x20000055 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1. laminar burning velocity measurement H2 O2 He
x20000056.xml 10.24388/ x20000056 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1. laminar burning velocity measurement H2 O2 He
x20000057.xml 10.24388/ x20000057 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1. Fig. 1. lower, full square laminar burning velocity measurement H2 O2 He
x20000058.xml 10.24388/ x20000058 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1. Fig. 1. upper, full square laminar burning velocity measurement H2 O2 He
x20000059.xml 10.24388/ x20000059 Burke. M.P., Dryer, F.L., Ju, Y., Proceedings of the Combustion Institute, (33), 905-912, 2011, Electr. Suppl. Table S1. laminar burning velocity measurement H2 O2 He
x20000060.xml 10.24388/ x20000060 Qiao, L., Gu, Y., Dahm, W.J.A., Oran, E.S., Faeth, G.M., Combustion and Flame, (151), 196-208, 2007, Fig. 3., full inverse triangle laminar burning velocity measurement H2 O2 N2 He
x20000061.xml 10.24388/ x20000061 Qiao, L., Gu, Y., Dahm, W.J.A., Oran, E.S., Faeth, G.M., Combustion and Flame, (151), 196-208, 2007, Fig. 3., full triangle laminar burning velocity measurement H2 O2 N2 Ar
x20000062.xml 10.24388/ x20000062 Qiao, L., Gu, Y., Dahm, W.J.A., Oran, E.S., Faeth, G.M., Combustion and Flame, (151), 196-208, 2007, Fig. 3., full circle laminar burning velocity measurement H2 O2 N2
x20000064.xml 10.24388/ x20000064 Qiao, L., Gu, Y., Dahm, W.J.A., Oran, E.S., Faeth, G.M., Combustion and Flame, (151), 196-208, 2007, Fig. 4., full triangle laminar burning velocity measurement H2 O2 N2 Ar
x20000065_x.xml 10.24388/ x20000065_x Qiao, L., Gu, Y., Dahm, W.J.A., Oran, E.S., Faeth, G.M., Combustion and Flame, (151), 196-208, 2007, Fig. 4., full circle laminar burning velocity measurement H2 O2 N2
x20000067.xml 10.24388/ x20000067 Qiao, L., Gu, Y., Dahm, W.J.A., Oran, E.S., Faeth, G.M., Combustion and Flame, (151), 196-208, 2007, Fig. 5., open circle laminar burning velocity measurement H2 O2 N2
x20000069.xml 10.24388/ x20000069 Vandooren, J., Bian, J., Twenty-Third Symposium (Internationl) on Combustion/The Combustion Institute, 341-346, 1990, Fig. 1-6., star burner stabilized flame speciation measurement H2 O2 N2
x20000070_x.xml 10.24388/ x20000070_x Qin, X., Kobayashi, H., Niioka, T., Experimental Thermal and Fluid Science, (21) 58-63, 2000, Fig. 2. full circle laminar burning velocity measurement H2 O2 N2
x20000071_x.xml 10.24388/ x20000071_x Qin, X., Kobayashi, H., Niioka, T., Experimental Thermal and Fluid Science, (21) 58-63, 2000, Fig. 4a. full circle laminar burning velocity measurement H2 O2 N2
x20000072_x.xml 10.24388/ x20000072_x Qin, X., Kobayashi, H., Niioka, T., Experimental Thermal and Fluid Science, (21) 58-63, 2000, Fig. 4b. full triangle laminar burning velocity measurement H2 O2 N2
x20000073_x.xml 10.24388/ x20000073_x Qin, X., Kobayashi, H., Niioka, T., Experimental Thermal and Fluid Science, (21) 58-63, 2000, Fig. 4c. full square laminar burning velocity measurement H2 O2 N2
x20000074.xml 10.24388/ x20000074 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, open blue diamond, H2/(CO+ H2) = 100% laminar burning velocity measurement H2 O2 N2
x20000074burn.xml 10.24388/ x20000074burn Paletskii, A.A., Kuibida, L.V., Bolshova, T.A., Korobeinichev, O.P., Fristrom, R.M., Combustion, Explosion, and Shock Waves, (32), (3), 245-250 , 1996, Fig. 1. all burner stabilized flame speciation measurement H2 O2 N2
x20000075.xml 10.24388/ x20000075 J. Santner; F. L. Dryer; Y. Ju, Proceedings of the Combustion Institute 2013, 34, 719-726, Calculated from mass burning rate, Fig. 2 top, orangle triangle laminar burning velocity measurement H2 O2 He
x20000075burn.xml 10.24388/ x20000075burn Paletskii, A.A., Kuibida, L.V., Bolshova, T.A., Korobeinichev, O.P., Fristrom, R.M., Combustion, Explosion, and Shock Waves, (32), (3), 245-250 , 1996, Fig. 2. all burner stabilized flame speciation measurement H2 O2 N2
x20000076.xml 10.24388/ x20000076 J. Santner; F. L. Dryer; Y. Ju, Proceedings of the Combustion Institute 2013, 34, 719-726, Calculated from mass burning rate, Fig. 2 top, blue diamond laminar burning velocity measurement H2 O2 He H2O
x20000077.xml 10.24388/ x20000077 J. Santner; F. L. Dryer; Y. Ju, Proceedings of the Combustion Institute 2013, 34, 719-726, Calculated from mass burning rate, Fig. 2 top, green circle laminar burning velocity measurement H2 O2 He H2O
x20001001.xml 10.24388/ x20001001 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 10., full triangle, H2/CO = 50/50 laminar burning velocity measurement H2 CO Ar O2
x20001002.xml 10.24388/ x20001002 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 10., full diamond, H2/CO = 10/90 laminar burning velocity measurement H2 CO Ar O2
x20001003.xml 10.24388/ x20001003 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 12., full diamond, bath gas: CO2 laminar burning velocity measurement H2 O2 CO2
x20001004.xml 10.24388/ x20001004 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 12., full square, bath gas: CO2 laminar burning velocity measurement H2 O2 CO2
x20001005.xml 10.24388/ x20001005 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 12., full circle, bath gas: CO2 laminar burning velocity measurement H2 O2 CO2
x20001006.xml 10.24388/ x20001006 Burke, M.P., Chaos, M., Dryer, F.L., Ju, Y., Combustion and Flame, (157), 618-631, 2010, Suppl. Mat. Table A1, Fig. 12., full triangle, bath gas: CO2 laminar burning velocity measurement H2 O2 CO2
x20001007.xml 10.24388/ x20001007 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 4, open circle laminar burning velocity measurement H2 CO O2 N2 H2O
x20001008.xml 10.24388/ x20001008 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 4, open square laminar burning velocity measurement H2 CO O2 N2 H2O
x20001009.xml 10.24388/ x20001009 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 4, open diamond laminar burning velocity measurement H2 CO O2 N2 H2O
x20001010.xml 10.24388/ x20001010 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 4, open triangle laminar burning velocity measurement H2 CO O2 N2 H2O
x20001013.xml 10.24388/ x20001013 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 6, open diamond laminar burning velocity measurement H2 CO O2 N2 H2O
x20001014.xml 10.24388/ x20001014 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 6, open circle laminar burning velocity measurement H2 CO O2 N2 H2O
x20001015.xml 10.24388/ x20001015 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 6, open square laminar burning velocity measurement H2 CO O2 N2 H2O
x20001016.xml 10.24388/ x20001016 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig.7, open square laminar burning velocity measurement H2 CO O2 N2 H2O
x20001017.xml 10.24388/ x20001017 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 7, open triangle laminar burning velocity measurement H2 CO O2 N2 H2O
x20001018.xml 10.24388/ x20001018 Das, A.K., Kumar, K., Sung, C.-J., Combustion and Flame, (158), 345-353, 2011, Suppl. Mat. Table, Fig. 7, full circle laminar burning velocity measurement H2 CO O2 N2 H2O
x20001022.xml 10.24388/ x20001022 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, top, H2/CO = 50/50, red circle laminar burning velocity measurement CO H2 O2 N2
x20001023.xml 10.24388/ x20001023 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, top, H2/CO = 75/25, orange triangle laminar burning velocity measurement CO H2 O2 N2
x20001024.xml 10.24388/ x20001024 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, top, H2/CO = 5/95, yellow square laminar burning velocity measurement CO H2 O2 N2
x20001025.xml 10.24388/ x20001025 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, top, H2/CO = 50/50, red circle laminar burning velocity measurement CO H2 O2 He
x20001026.xml 10.24388/ x20001026 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, top, H2/CO = 50/50, yellow triangle laminar burning velocity measurement CO H2 O2 He
x20001027.xml 10.24388/ x20001027 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, middle, H2/CO = 25/75, red circle laminar burning velocity measurement CO H2 O2 He
x20001028.xml 10.24388/ x20001028 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, middle, H2/CO = 25/75, orange triangle laminar burning velocity measurement CO H2 O2 He
x20001029.xml 10.24388/ x20001029 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, middle, H2/CO = 25/75, yellow square laminar burning velocity measurement CO H2 O2 He
x20001030.xml 10.24388/ x20001030 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, bottom, H2/CO = 5/95, red circle laminar burning velocity measurement CO H2 O2 He
x20001031.xml 10.24388/ x20001031 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, bottom, H2/CO = 5/95, orange triangle laminar burning velocity measurement CO H2 O2 He
x20001032.xml 10.24388/ x20001032 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, bottom, H2/CO = 5/95, yellow square laminar burning velocity measurement CO H2 O2 He
x20001033.xml 10.24388/ x20001033 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 2, bottom, H2/CO = 5/95, green diamond laminar burning velocity measurement CO H2 O2 He
x20001034.xml 10.24388/ x20001034 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 2, open red triangle laminar burning velocity measurement CO H2 O2 He
x20001035.xml 10.24388/ x20001035 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 3, open dark blue diamond laminar burning velocity measurement CO H2 O2 N2
x20001036.xml 10.24388/ x20001036 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 3, open red triangle laminar burning velocity measurement CO H2 O2 N2
x20001037.xml 10.24388/ x20001037 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 3, open green square laminar burning velocity measurement CO H2 O2 N2
x20001038.xml 10.24388/ x20001038 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 3, open brown circle laminar burning velocity measurement CO H2 O2 N2
x20001039.xml 10.24388/ x20001039 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 3, blue star laminar burning velocity measurement CO H2 O2 N2
x20001040.xml 10.24388/ x20001040 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 4, open triangle laminar burning velocity measurement CO H2 O2 He
x20001041.xml 10.24388/ x20001041 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 5, open diamond laminar burning velocity measurement CO H2 O2 He
x20001042.xml 10.24388/ x20001042 Natarajan, J.; Kochar, Y.; Lieuwen, T.; Seitzman, J., Proceedings of the Combustion Institute 2009, 32, 1261-1268, Fig. 8, open triangle laminar burning velocity measurement CO H2 O2 He CO2
x20001043.xml 10.24388/ x20001043 C. Prathap; A. Ray; M. R. Ravi, Combustion and Flame 2008, 155, 145-160, Table 1 laminar burning velocity measurement CO H2 O2 N2
x20001044.xml 10.24388/ x20001044 C. Prathap; A. Ray; M. R. Ravi, Combustion and Flame 2008, 155, 145-160, Table 2 laminar burning velocity measurement CO H2 O2 N2
x20001045.xml 10.24388/ x20001045 C. Prathap; A. Ray; M. R. Ravi, Combustion and Flame 2008, 155, 145-160, Table 3 laminar burning velocity measurement CO H2 O2 N2
x20001046.xml 10.24388/ x20001046 C. Prathap; A. Ray; M. R. Ravi, Combustion and Flame 2008, 155, 145-160, Table 4 laminar burning velocity measurement CO H2 O2 N2
x20001049.xml 10.24388/ x20001049 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 70/30, full pink square laminar burning velocity measurement CO H2 O2 N2
x20001050.xml 10.24388/ x20001050 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 60/40, full red triangle laminar burning velocity measurement CO H2 O2 N2
x20001051.xml 10.24388/ x20001051 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 50/50, full dark blue diamond laminar burning velocity measurement CO H2 O2 N2
x20001052.xml 10.24388/ x20001052 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 30/70, full yellow diamond laminar burning velocity measurement CO H2 O2 N2
x20001053.xml 10.24388/ x20001053 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 40/60, full black circle laminar burning velocity measurement CO H2 O2 N2
x20001054.xml 10.24388/ x20001054 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 20/80, full green triangle laminar burning velocity measurement CO H2 O2 N2
x20001055.xml 10.24388/ x20001055 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 7, H2/CO = 10/90, full blue circle laminar burning velocity measurement CO H2 O2 N2
x20001056.xml 10.24388/ x20001056 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 8, H2/CO = 10/90, full dark blue diamond laminar burning velocity measurement CO H2 O2 N2
x20001057.xml 10.24388/ x20001057 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 8, H2/CO = 5/95, full pink square laminar burning velocity measurement CO H2 O2 N2
x20001058.xml 10.24388/ x20001058 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 8, H2/CO = 3/97, full red triangle laminar burning velocity measurement CO H2 O2 N2
x20001059.xml 10.24388/ x20001059 N. Bouvet; S. Y. Lee; I. Gökalp; R. J. Santoro, Proceedings of the European Combustion Meeting 2007, 3, 6-17, Fig. 8, H2/CO = 1/99, full green circle laminar burning velocity measurement CO H2 O2 N2
x20001060.xml 10.24388/ x20001060 I. C. McLean; D. B. Smith; S. C. Taylor, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 749-757, open circle laminar burning velocity measurement CO H2 O2 N2
x20001061.xml 10.24388/ x20001061 I. C. McLean; D. B. Smith; S. C. Taylor, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 749-757, open diamond laminar burning velocity measurement CO H2 O2 N2
x20001062.xml 10.24388/ x20001062 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 4, lower full black square laminar burning velocity measurement CO H2 O2 N2
x20001063.xml 10.24388/ x20001063 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 7, full black square laminar burning velocity measurement CO H2 O2 N2
x20001064.xml 10.24388/ x20001064 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 7, full black triangle laminar burning velocity measurement CO H2 O2 N2
x20001065.xml 10.24388/ x20001065 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 7, full black circle laminar burning velocity measurement CO H2 O2 N2
x20001066.xml 10.24388/ x20001066 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 7, full black diamond laminar burning velocity measurement CO H2 O2 N2
x20001067.xml 10.24388/ x20001067 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 8, full black triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001068.xml 10.24388/ x20001068 H. J. Burbano; J. Pareja; A. A. Amell, International Journal of Hydrogen Energy 2011, 36, (4), 3232-3242, Fig. 8, full black diamond laminar burning velocity measurement CO H2 O2 N2 CO2
x20001069.xml 10.24388/ x20001069 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 5, H2/CO = 50/50, 0% CO2 dilution, dark blue square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001070.xml 10.24388/ x20001070 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 5, H2/CO = 50/50, 20% CO2 dilution, red triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001071.xml 10.24388/ x20001071 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 7, H2/CO = 5/95, 0% CO2 dilution, dark blue square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001072.xml 10.24388/ x20001072 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 7, H2/CO = 5/95, 10% CO2 dilution, red triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001073_x.xml 10.24388/ x20001073_x J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 7, H2/CO = 95/5, 0% CO2 dilution, dark blue square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001074.xml 10.24388/ x20001074 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 7, H2/CO = 95/5, 20% CO2 dilution, red triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001075.xml 10.24388/ x20001075 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 12, H2/CO = 5/95, 0% CO2 dilution, blue star laminar burning velocity measurement CO H2 O2 N2 CO2
x20001076.xml 10.24388/ x20001076 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 12, H2/CO = 5/95, 0% CO2 dilution, brown circle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001077.xml 10.24388/ x20001077 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 12, H2/CO = 5/95, 0% CO2 dilution, green square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001078.xml 10.24388/ x20001078 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 12, H2/CO = 5/95, 0% CO2 dilution, red triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001079.xml 10.24388/ x20001079 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 12, H2/CO = 5/95, 0% CO2 dilution, dark blue diamond laminar burning velocity measurement CO H2 O2 N2 CO2
x20001080.xml 10.24388/ x20001080 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 13, H2/CO = 95/5, 0% CO2 dilution, blue circle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001081.xml 10.24388/ x20001081 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 13, H2/CO = 95/5, 0% CO2 dilution, green square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001082.xml 10.24388/ x20001082 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 13, H2/CO = 95/5, 0% CO2 dilution, red triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001083.xml 10.24388/ x20001083 J. Natarajan; T. Lieuwen; J. Seitzman, Combustion and Flame 2007, 151, (1-2), 104-119, Fig. 13, H2/CO = 95/5, 0% CO2 dilution, dark blue diamond laminar burning velocity measurement CO H2 O2 N2 CO2
x20001084.xml 10.24388/ x20001084 N. Bouvet; C. Chauveau; I. Gökalp; F. Halter, Proceedings of the Combustion Institute 2011, 33, (1), 913-920, Fig. 5, H2/CO = 5/95, full yellow square laminar burning velocity measurement CO H2 O2 N2
x20001085.xml 10.24388/ x20001085 N. Bouvet; C. Chauveau; I. Gökalp; F. Halter, Proceedings of the Combustion Institute 2011, 33, (1), 913-920, Fig. 6, H2/CO = 10/90, full yellow square laminar burning velocity measurement CO H2 O2 N2
x20001086_x.xml 10.24388/ x20001086_x N. Bouvet; C. Chauveau; I. Gökalp; F. Halter, Proceedings of the Combustion Institute 2011, 33, (1), 913-920, Fig. 7, H2/CO = 25/75, full yellow square laminar burning velocity measurement CO H2 O2 N2
x20001087_x.xml 10.24388/ x20001087_x N. Bouvet; C. Chauveau; I. Gökalp; F. Halter, Proceedings of the Combustion Institute 2011, 33, (1), 913-920, Fig. 8, H2/CO = 50/50, full yellow square laminar burning velocity measurement CO H2 O2 N2
x20001088.xml 10.24388/ x20001088 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 5/95 laminar burning velocity measurement CO H2 O2 N2
x20001089.xml 10.24388/ x20001089 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 10/90 laminar burning velocity measurement CO H2 O2 N2
x20001090_x.xml 10.24388/ x20001090_x M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 25/75 laminar burning velocity measurement CO H2 O2 N2
x20001091.xml 10.24388/ x20001091 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 50/50 laminar burning velocity measurement CO H2 O2 N2
x20001092.xml 10.24388/ x20001092 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 2, H2/CO/CO2 = 5/95/0, open square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001093.xml 10.24388/ x20001093 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 2, H2/CO/CO2 = 5/45/50, half filled open square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001094.xml 10.24388/ x20001094 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 3, H2/CO/CO2 = 40/10/50, open circle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001095.xml 10.24388/ x20001095 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 3, H2/CO/CO2 = 25/25/50, open square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001096.xml 10.24388/ x20001096 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 3, H2/CO/CO2 = 10/40/50, open diamond laminar burning velocity measurement CO H2 O2 N2 CO2
x20001097.xml 10.24388/ x20001097 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 8, H2/CO/CO2 = 32/8/60, open circle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001098.xml 10.24388/ x20001098 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 8, H2/CO/CO2 = 20/20/60, open reverse triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001099.xml 10.24388/ x20001099 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 8, H2/CO/CO2 = 8/32/60, open square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001100.xml 10.24388/ x20001100 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 9, H2/CO/CO2 = 48/12/40, open circle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001101.xml 10.24388/ x20001101 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 9, H2/CO/CO2 = 30/30/40, open reverse triangle laminar burning velocity measurement CO H2 O2 N2 CO2
x20001102.xml 10.24388/ x20001102 V. Ratna Kishore; M. R. Ravi; A. Ray, Combustion and Flame 2011, 158, (11), 2149-2164, Fig. 9, H2/CO/CO2 = 12/48/40, open square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001103.xml 10.24388/ x20001103 A. A. Konnov; I. V. Dyakov; J. De Ruyck, Proceedings Of The Combustion Institute 2003, 29, 2171-2177, H2/CO/CO2 = 5.05/44.75/50.2, cross laminar burning velocity measurement CO H2 O2 N2 CO2
x20001104.xml 10.24388/ x20001104 A. A. Konnov; I. V. Dyakov; J. De Ruyck, Proceedings Of The Combustion Institute 2003, 29, 2171-2177, H2/CO/CO2 = 5.05/44.75/50.2, open square laminar burning velocity measurement CO H2 O2 N2 CO2
x20001105.xml 10.24388/ x20001105 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 3/97 laminar burning velocity measurement CO H2 O2 N2
x20001106.xml 10.24388/ x20001106 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 5/95, p = 0.5 atm laminar burning velocity measurement CO H2 O2 N2
x20001107.xml 10.24388/ x20001107 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 5/95, p = 2 atm laminar burning velocity measurement CO H2 O2 N2
x20001108.xml 10.24388/ x20001108 M. I. Hassan; K. T. Aung; G. M. Faeth, Journal of Propulsion and Power 1997, 13, (2), 239-245; Table 1, H2/CO = 5/95, p = 4 atm laminar burning velocity measurement CO H2 O2 N2
x20001109.xml 10.24388/ x20001109 Y. Huang; C. J. Sung; J. A. Eng, Combustion and Flame 2004, 139, 239-251, Fig. 13, H2/CO/N2 = 28/25/47, open circle laminar burning velocity measurement CO H2 O2 N2
x20001110.xml 10.24388/ x20001110 C. M. Vagelopoulos; F. N. Egolfopoulos, Proceedings of the Combustion Institute 1994, 25, 1317-1323, Fig. 1, (XCO+XH2) = 0.20, H2/CO ratio varied laminar burning velocity measurement H2 CO O2 N2
x20001111.xml 10.24388/ x20001111 C. M. Vagelopoulos; F. N. Egolfopoulos, Proceedings of the Combustion Institute 1994, 25, 1317-1323, Fig. 1, (XCO+XH2) = 0.17, H2/CO ratio varied laminar burning velocity measurement H2 CO O2 N2
x20001112.xml 10.24388/ x20001112 C. M. Vagelopoulos; F. N. Egolfopoulos, Proceedings of the Combustion Institute 1994, 25, 1317-1323, Fig. 1, (XCO+XH2) = 0.14, H2/CO ratio varied laminar burning velocity measurement H2 CO O2 N2
x20001113.xml 10.24388/ x20001113 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.985 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001114.xml 10.24388/ x20001114 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.80 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001115.xml 10.24388/ x20001115 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.60 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001116.xml 10.24388/ x20001116 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.40 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001117.xml 10.24388/ x20001117 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.30 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001118.xml 10.24388/ x20001118 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.21 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001119.xml 10.24388/ x20001119 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.17 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001120.xml 10.24388/ x20001120 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 190, H2/CO/O2/N2/H2O, f = 0.13 laminar burning velocity measurement H2 CO O2 N2 H2O
x20001121.xml 10.24388/ x20001121 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 191, CO/O2/N2/H2O, f = 0.985 laminar burning velocity measurement CO O2 N2 H2O
x20001122.xml 10.24388/ x20001122 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 191, CO/O2/N2/H2O, f = 0.21 laminar burning velocity measurement CO O2 N2 H2O
x20001123.xml 10.24388/ x20001123 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 192, H2/CO/O2/CO2/H2O, f = 1.00 laminar burning velocity measurement H2 CO O2 H2O
x20001124.xml 10.24388/ x20001124 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 192, H2/CO/O2/CO2/H2O, f = 0.80 laminar burning velocity measurement H2 CO O2 CO2 H2O
x20001125.xml 10.24388/ x20001125 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 192, H2/CO/O2/CO2/H2O, f = 0.60 laminar burning velocity measurement H2 CO O2 CO2 H2O
x20001126.xml 10.24388/ x20001126 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 192, H2/CO/O2/CO2/H2O, f = 0.40 laminar burning velocity measurement H2 CO O2 CO2 H2O
x20001127.xml 10.24388/ x20001127 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 192, H2/CO/O2/CO2/H2O, f = 0.30 laminar burning velocity measurement H2 CO O2 CO2 H2O
x20001128.xml 10.24388/ x20001128 B. Lewis; G. von Elbe, Combustion, Flames and Explosions of Gases. 2nd ed.; Academic Press: New York and London, 1961, Fig. 192, H2/CO/O2/CO2/H2O, f = 0.21 laminar burning velocity measurement H2 CO O2 CO2 H2O
x20001129.xml 10.24388/ x20001129 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 2, 75% H2, 25% CO laminar burning velocity measurement H2 CO O2 N2
x20001130.xml 10.24388/ x20001130 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 2, 25% H2, 75% CO laminar burning velocity measurement H2 CO O2 N2
x20001131.xml 10.24388/ x20001131 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 2, 5% H2, 95% CO laminar burning velocity measurement H2 CO O2 N2
x20001132.xml 10.24388/ x20001132 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 3, 50% H2, 50% CO, T = 500 K laminar burning velocity measurement H2 CO O2 N2
x20001133.xml 10.24388/ x20001133 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 3, 50% H2, 50% CO, T = 400 K laminar burning velocity measurement H2 CO O2 N2
x20001134.xml 10.24388/ x20001134 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 3, 50% H2, 50% CO, T = 298 K laminar burning velocity measurement H2 CO O2 N2
x20001135.xml 10.24388/ x20001135 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 5, 50% H2, 50% CO, varying H2O addition laminar burning velocity measurement H2 CO O2 N2 H2O
x20001136.xml 10.24388/ x20001136 D. Singh; T. Nishiie; S. Tanvir; L. Qiao, Fuel 2012, 94, (0), 448-456, Fig. 5, 5% H2, 95% CO, varying H2O addition laminar burning velocity measurement H2 CO O2 N2 H2O
x20001137.xml 10.24388/ x20001137 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, top, H2/CO = 5/95, green diamond laminar burning velocity measurement CO H2 O2 N2
x20001138.xml 10.24388/ x20001138 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, bottom, H2/CO = 50/50, red circle laminar burning velocity measurement CO H2 O2 N2
x20001139.xml 10.24388/ x20001139 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, bottom, H2/CO = 25/75, orange circle laminar burning velocity measurement CO H2 O2 N2
x20001140.xml 10.24388/ x20001140 Sun, H.; Wang, S. I.; Jomaas, G.; Law, C. K., Proceedings of the Combustion Institute 2007, 31, 439-446, Fig. 1, bottom, H2/CO = 5/95, yellow triangle laminar burning velocity measurement CO H2 O2 N2
x20001142.xml 10.24388/ x20001142 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 3, CO/(CO+H2) = 0.303 laminar burning velocity measurement CO H2 O2 N2
x20001143.xml 10.24388/ x20001143 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 3, CO/(CO+H2) = 0.567 laminar burning velocity measurement CO H2 O2 N2
x20001144.xml 10.24388/ x20001144 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 3, CO/(CO+H2) = 0.759 laminar burning velocity measurement CO H2 O2 N2
x20001145.xml 10.24388/ x20001145 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 3, CO/(CO+H2) = 0.895 laminar burning velocity measurement CO H2 O2 N2
x20001146.xml 10.24388/ x20001146 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 3, CO/(CO+H2) = 0.97 laminar burning velocity measurement CO H2 O2 N2
x20001147.xml 10.24388/ x20001147 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 3, CO/(CO+H2) = 0.9945 laminar burning velocity measurement CO H2 O2 N2
x20001148.xml 10.24388/ x20001148 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 4, full circle, CO/(CO+H2) = 0.9945, 2.30% H2O addition laminar burning velocity measurement CO H2 O2 H2O N2
x20001149.xml 10.24388/ x20001149 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 4, vertically struck circle, CO/(CO+H2) = 0.9945, 1.87% H2O addition laminar burning velocity measurement CO H2 O2 H2O N2
x20001150.xml 10.24388/ x20001150 T. G. Scholte; P. B. Vaags, Combustion and Flame 1959, 3, (0), 511-524, data in: M. A. Cherian; P. Rhodes; R. J. Simpson; G. Dixon-Lewis, Proceedings of the Combustion Institute 1981, 18, 385-396, Data from Cherian et al, Fig. 4, open circle, CO/(CO+H2) = 0.9945, 1.20% H2O addition laminar burning velocity measurement CO H2 O2 H2O N2
x20001151.xml 10.24388/ x20001151 M. C. Krejci; A. J. Vissotski; S. Ravi; W. K. Metcalfe; A. Keromnes; H. J. Curran; E. L. Petersen, Proceedings of the Combustion Institute 2012, 34, in press, Table A1, H2/CO = 5/95, 7.5% H2O addition laminar burning velocity measurement H2 CO O2 N2 H2O
x20001152.xml 10.24388/ x20001152 M. C. Krejci; A. J. Vissotski; S. Ravi; W. K. Metcalfe; A. Keromnes; H. J. Curran; E. L. Petersen, Proceedings of the Combustion Institute 2012, 34, in press, Table A1, H2/CO = 50/50, no H2O addition laminar burning velocity measurement H2 CO O2 He
x20001153.xml 10.24388/ x20001153 M. C. Krejci; A. J. Vissotski; S. Ravi; W. K. Metcalfe; A. Keromnes; H. J. Curran; E. L. Petersen, Proceedings of the Combustion Institute 2012, 34, in press, Table A2, H2/CO = 5/95, 15% H2O addition laminar burning velocity measurement H2 CO O2 He H2O
x20001154.xml 10.24388/ x20001154 M. C. Krejci; A. J. Vissotski; S. Ravi; W. K. Metcalfe; A. Keromnes; H. J. Curran; E. L. Petersen, Proceedings of the Combustion Institute 2012, 34, in press, Table A2, H2/CO = 50/50, 7.5% H2O addition laminar burning velocity measurement H2 CO O2 He H2O
x20001155.xml 10.24388/ x20001155 M. C. Krejci; A. J. Vissotski; S. Ravi; W. K. Metcalfe; A. Keromnes; H. J. Curran; E. L. Petersen, Proceedings of the Combustion Institute 2012, 34, in press, Table A3, H2/CO = 50/50, 15% H2O addition laminar burning velocity measurement H2 CO O2 N2 H2O
x20001156.xml 10.24388/ x20001156 M. C. Krejci; A. J. Vissotski; S. Ravi; W. K. Metcalfe; A. Keromnes; H. J. Curran; E. L. Petersen, Proceedings of the Combustion Institute 2012, 34, in press, Table A3, H2/CO = 5/95, no H2O addition laminar burning velocity measurement H2 CO O2 He
x20001157.xml 10.24388/ x20001157 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 18, full circle, H2/CO = 67/33 laminar burning velocity measurement H2 CO O2 N2
x20001158.xml 10.24388/ x20001158 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20a, open circle, H2/CO = 67/33, N2 dilution, dilution ratio 0.1 laminar burning velocity measurement H2 CO O2 N2
x20001159_x.xml 10.24388/ x20001159_x X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20a, open triangle, H2/CO = 67/33, N2 dilution, dilution ratio 0.2 laminar burning velocity measurement H2 CO O2 N2
x20001160_x.xml 10.24388/ x20001160_x X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20a, open reverse triangle, H2/CO = 67/33, N2 dilution, dilution ratio 0.3 laminar burning velocity measurement H2 CO O2 N2
x20001161.xml 10.24388/ x20001161 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20a, open diamond, H2/CO = 67/33, N2 dilution, dilution ratio 0.4 laminar burning velocity measurement H2 CO O2 N2
x20001162.xml 10.24388/ x20001162 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20b, open circle, H2/CO = 67/33, CO2 dilution, dilution ratio 0.1 laminar burning velocity measurement H2 CO O2 N2 CO2
x20001163_x.xml 10.24388/ x20001163_x X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20b, open triangle, H2/CO = 67/33, CO2 dilution, dilution ratio 0.2 laminar burning velocity measurement H2 CO O2 N2 CO2
x20001164.xml 10.24388/ x20001164 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20b, open reverse triangle, H2/CO = 67/33, CO2 dilution, dilution ratio 0.3 laminar burning velocity measurement H2 CO O2 N2 CO2
x20001165.xml 10.24388/ x20001165 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 20b, open diamond, H2/CO = 67/33, CO2 dilution, dilution ratio 0.4 laminar burning velocity measurement H2 CO O2 N2 CO2
x20001166.xml 10.24388/ x20001166 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full black square, H2/(CO+ H2) = 0% laminar burning velocity measurement CO O2 N2
x20001167.xml 10.24388/ x20001167 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full red diamond, H2/(CO+ H2) = 10% laminar burning velocity measurement CO H2 O2 N2
x20001168.xml 10.24388/ x20001168 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full blue triangle, H2/(CO+ H2) = 20% laminar burning velocity measurement CO H2 O2 N2
x20001169.xml 10.24388/ x20001169 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full sea green triangle, H2/(CO+ H2) = 30% laminar burning velocity measurement CO H2 O2 N2
x20001170.xml 10.24388/ x20001170 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full pink triangle, H2/(CO+ H2) = 40% laminar burning velocity measurement CO H2 O2 N2
x20001171.xml 10.24388/ x20001171 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full olive triangle, H2/(CO+ H2) = 50% laminar burning velocity measurement CO H2 O2 N2
x20001172.xml 10.24388/ x20001172 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full dark blue diamond, H2/(CO+ H2) = 60% laminar burning velocity measurement CO H2 O2 N2
x20001173.xml 10.24388/ x20001173 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full dark red circle, H2/(CO+ H2) = 70% laminar burning velocity measurement CO H2 O2 N2
x20001174.xml 10.24388/ x20001174 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, full magenta circle, H2/(CO+ H2) = 80% laminar burning velocity measurement CO H2 O2 N2
x20001175.xml 10.24388/ x20001175 C. Dong; Q. Zhou; Q. Zhao; Y. Zhang; T. Xu; S. Hui, Fuel 2009, 88, (10), 1858-1863, Fig. 6, green asterisk, H2/(CO+ H2) = 90% laminar burning velocity measurement CO H2 O2 N2
x20001176.xml 10.24388/ x20001176 M. P. Burke; X. Qin; Y. Ju; F. L. Dryer, in: 5th US Combustion Meeting Organized by the Western States Section of the Combustion Institute, University of California at San Diego, March 25-28, 2007, Paper #A16, Fig. 6, full square laminar burning velocity measurement CO H2 O2 N2
x20001177.xml 10.24388/ x20001177 M. P. Burke; X. Qin; Y. Ju; F. L. Dryer, in: 5th US Combustion Meeting Organized by the Western States Section of the Combustion Institute, University of California at San Diego, March 25-28, 2007, Paper #A16, Fig. 7a, full triangle laminar burning velocity measurement CO H2 O2 He
x20001178.xml 10.24388/ x20001178 M. P. Burke; X. Qin; Y. Ju; F. L. Dryer, in: 5th US Combustion Meeting Organized by the Western States Section of the Combustion Institute, University of California at San Diego, March 25-28, 2007, Paper #A16, Fig. 7a, full diamond laminar burning velocity measurement CO H2 O2 He
x20001179.xml 10.24388/ x20001179 M. P. Burke; X. Qin; Y. Ju; F. L. Dryer, in: 5th US Combustion Meeting Organized by the Western States Section of the Combustion Institute, University of California at San Diego, March 25-28, 2007, Paper #A16, Fig. 7b, full triangle laminar burning velocity measurement CO H2 O2 He CO2
x20001180.xml 10.24388/ x20001180 J. Santner; F. L. Dryer; Y. Ju, Proceedings of the Combustion Institute 2012, 34, in press, Calculated from mass burning rate, CO/H2 = 50/50, no H2O dilution laminar burning velocity measurement O2 He H2 CO
x20001181.xml 10.24388/ x20001181 J. Santner; F. L. Dryer; Y. Ju, Proceedings of the Combustion Institute 2012, 34, in press, Calculated from mass burning rate, CO/H2 = 50/50, 5% H2O dilution laminar burning velocity measurement O2 He H2O H2 CO
x20001182.xml 10.24388/ x20001182 J. Santner; F. L. Dryer; Y. Ju, Proceedings of the Combustion Institute 2012, 34, in press, Calculated from mass burning rate, CO/H2 = 50/50, 15% H2O dilution laminar burning velocity measurement O2 He H2O H2 CO
x20001183.xml 10.24388/ x20001183 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 11, full red circle, H2/CO = 1, air, 60% N2 dilution laminar burning velocity measurement H2 CO O2 N2
x20001184.xml 10.24388/ x20001184 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 12, full blue circle, H2/CO = 2, air, 70% N2 dilution laminar burning velocity measurement H2 CO O2 N2
x20001185.xml 10.24388/ x20001185 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 13, full black diamond, H2/CO = 2, air, 80% dilution (70% N2, 10% CO2) laminar burning velocity measurement H2 CO O2 N2 CO2
x20001186.xml 10.24388/ x20001186 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 13, full blue reverse triangle, H2/CO = 3, air, 80% dilution (70% N2, 10% CO2) laminar burning velocity measurement H2 CO O2 N2 CO2
x20001187.xml 10.24388/ x20001187 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 13, full green triangle, H2/CO = 4, air, 80% dilution (70% N2, 10% CO2) laminar burning velocity measurement H2 CO O2 N2 CO2
x20001188.xml 10.24388/ x20001188 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 14, full red circle, H2/CO = 2, air, 70% dilution (60% N2, 10% CO2) laminar burning velocity measurement H2 CO O2 N2 CO2
x20001189.xml 10.24388/ x20001189 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 14, full green triangle, H2/CO = 2, air, 60% dilution (50% N2, 10% CO2) laminar burning velocity measurement H2 CO O2 N2 CO2
x20001190.xml 10.24388/ x20001190 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 15, full green square, H2/CO = 3, air, 80% dilution (70% N2, 10% CO2), T = 325 K laminar burning velocity measurement H2 CO O2 N2 CO2
x20001191.xml 10.24388/ x20001191 B. Lohoefener; E. Roungos; S. Voss; D. Trimis, in: 2nd Heat Flux Burner Workshop, Warsaw University of Technology, Poland, 2012; pp July 29, 2012, Fig. p. 15, full red triangle, H2/CO = 3, air, 80% dilution (70% N2, 10% CO2), T = 350 K laminar burning velocity measurement H2 CO O2 N2 CO2
x20001192.xml 10.24388/ x20001192 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 17a, open circle, H2/CO = 66.7/33.3, T = 360 K laminar burning velocity measurement H2 CO O2 N2
x20001193.xml 10.24388/ x20001193 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 17a, open triangle, H2/CO = 66.7/33.3, T = 410 K laminar burning velocity measurement H2 CO O2 N2
x20001194.xml 10.24388/ x20001194 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 17b, open circle, H2/CO = 66.7/33.3, p = 2.5 bar laminar burning velocity measurement H2 CO O2 N2
x20001195.xml 10.24388/ x20001195 X. Zhang; Z. Huang; Z. Zhang; J. Zheng; W. Yu; D. Jiang, International Journal of Hydrogen Energy 2009, 34, (11), 4862-4875, Fig. 17b, open triangle, H2/CO = 66.7/33.3, p = 5 bar laminar burning velocity measurement H2 CO O2 N2
x20001196.xml 10.24388/ x20001196 W.B. Weng, Z.H. Wang, Y. He, Y.J. Zhou, J.H. Zhou, K.F. Cen: H2/CO Syngas Laminar Burning Velocity Measurement Using Teflon Coated Heat Flux Burner. Proc. Europ. Combust. Meeting 2013. Paper P3-4. Fig. 5, full circle laminar burning velocity measurement H2 CO O2 N2
x20001197.xml 10.24388/ x20001197 W.B. Weng, Z.H. Wang, Y. He, Y.J. Zhou, J.H. Zhou, K.F. Cen: H2/CO Syngas Laminar Burning Velocity Measurement Using Teflon Coated Heat Flux Burner. Proc. Europ. Combust. Meeting 2013. Paper P3-4. Fig. 6, full circle laminar burning velocity measurement H2 CO O2 N2
x20001198.xml 10.24388/ x20001198 W.B. Weng, Z.H. Wang, Y. He, Y.J. Zhou, J.H. Zhou, K.F. Cen: H2/CO Syngas Laminar Burning Velocity Measurement Using Teflon Coated Heat Flux Burner. Proc. Europ. Combust. Meeting 2013. Paper P3-4. Fig. 7, full circle laminar burning velocity measurement H2 CO O2 N2
x20001199.xml 10.24388/ x20001199 M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 1st data series laminar burning velocity measurement H2 CO O2 N2
x20001200.xml 10.24388/ x20001200 M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 2nd data series laminar burning velocity measurement H2 CO O2 He
x20001201.xml 10.24388/ x20001201 M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 3rd data series laminar burning velocity measurement H2 CO O2 N2
x20001202.xml 10.24388/ x20001202 M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 4th data series laminar burning velocity measurement H2 CO O2 N2
x20001203.xml 10.24388/ x20001203 M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 5th data series laminar burning velocity measurement H2 CO O2 He
x20001204.xml 10.24388/ x20001204 M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 6th data series laminar burning velocity measurement H2 CO O2 N2
x20001205_x.xml 10.24388/ x20001205_x M. Goswami, R.J.M. Bastiaans, A.A. Konnov, L.P.H. de Goey, Int. J. Hydrogen Energy, 2014, 39, 1485-1498, Suppl. Mat. Table 1, 7th data series laminar burning velocity measurement H2 CO O2 He
x20001206.xml 10.24388/ x20001206 J. S. Kim, J. Park, D. S. Bae, T. M. Vu, J. S. Ha, T. K. Kim, Int. J. Hydrogen Energy 35 (2010), 1390-1400, Fig. 2a, full circle laminar burning velocity measurement H2 CO O2 N2
x20001207.xml 10.24388/ x20001207 J. S. Kim, J. Park, D. S. Bae, T. M. Vu, J. S. Ha, T. K. Kim, Int. J. Hydrogen Energy 35 (2010), 1390-1400, Fig. 2b, full circle laminar burning velocity measurement H2 CO CO2 O2 N2
x20001208.xml 10.24388/ x20001208 F. Wu, A. P. Kelley, C. Tang, D. Zhu, C. K. Law, Int. J. Hydrogen Energy 35 (2011), 13171-13180, Fig. 2, top, open sircle laminar burning velocity measurement H2 CO O2 N2
x20001209.xml 10.24388/ x20001209 F. Wu, A. P. Kelley, C. Tang, D. Zhu, C. K. Law, Int. J. Hydrogen Energy 35 (2011), 13171-13180, Fig. 2, middle, open sircle laminar burning velocity measurement H2 CO O2 N2
x20001210.xml 10.24388/ x20001210 F. Wu, A. P. Kelley, C. Tang, D. Zhu, C. K. Law, Int. J. Hydrogen Energy 35 (2011), 13171-13180, Fig. 2, bottom, open sircle laminar burning velocity measurement H2 CO O2 N2
x20001211.xml 10.24388/ x20001211 F. Wu, A. P. Kelley, C. Tang, D. Zhu, C. K. Law, Int. J. Hydrogen Energy 35 (2011), 13171-13180, Fig. 14, open sircle laminar burning velocity measurement H2 CO O2 He
x20001212.xml 10.24388/ x20001212 S. Voss, S. Hartl, C. Hasse, Int. J. Hydrogen Energy, 2014, 39, 19810-19817, H2/CO/N2+air, H2/CO=0.5, 70% dilution series laminar burning velocity measurement H2 CO O2 N2
x20001213.xml 10.24388/ x20001213 S. Voss, S. Hartl, C. Hasse, Int. J. Hydrogen Energy, 2014, 39, 19810-19817, H2/CO/N2+air, H2/CO=1, 70% dilution series laminar burning velocity measurement H2 CO O2 N2
x20001214.xml 10.24388/ x20001214 S. Voss, S. Hartl, C. Hasse, Int. J. Hydrogen Energy, 2014, 39, 19810-19817, H2/CO/N2+air, H2/CO=1, 70% dilution series laminar burning velocity measurement H2 CO O2 N2
x20001215.xml 10.24388/ x20001215 S. Voss, S. Hartl, C. Hasse, Int. J. Hydrogen Energy, 2014, 39, 19810-19817, H2/CO/N2+air, H2/CO=4, 70% dilution series laminar burning velocity measurement H2 CO O2 N2
x20001216.xml 10.24388/ x20001216 S. Voss, S. Hartl, C. Hasse, Int. J. Hydrogen Energy, 2014, 39, 19810-19817, H2/CO/N2+air, H2/CO=2, 55-80% dilution series laminar burning velocity measurement H2 CO O2 N2
x20001217.xml 10.24388/ x20001217 S. Voss, S. Hartl, C. Hasse, Int. J. Hydrogen Energy, 2014, 39, 19810-19817, H2/CO/N2+air, H2/CO=0.75-3.0, 70% dilution series laminar burning velocity measurement H2 CO O2 N2
x20001218.xml 10.24388/ x20001218 Yang Zhang, Wenfeng Shen, Meng Fan, Hai Zhang, Suhui Li, 2014, private communication, Laminar flame speed studies of lean premixed H2/CO/air flames, Combust. Flame, 2014, in press; Fig. 4, full black square, phi = 0.4 laminar burning velocity measurement H2 CO O2 N2
x20001219.xml 10.24388/ x20001219 Yang Zhang, Wenfeng Shen, Meng Fan, Hai Zhang, Suhui Li, 2014, private communication, Laminar flame speed studies of lean premixed H2/CO/air flames, Combust. Flame, 2014, in press; Fig. 4, full red circle, phi=0.5 laminar burning velocity measurement H2 CO O2 N2
x20001220.xml 10.24388/ x20001220 Yang Zhang, Wenfeng Shen, Meng Fan, Hai Zhang, Suhui Li, 2014, private communication, Laminar flame speed studies of lean premixed H2/CO/air flames, Combust. Flame, 2014, in press; Fig. 4, full blue triangle, phi = 0.6 laminar burning velocity measurement H2 CO O2 N2
x20001221.xml 10.24388/ x20001221 Yang Zhang, Wenfeng Shen, Meng Fan, Hai Zhang, Suhui Li, 2014, private communication, Laminar flame speed studies of lean premixed H2/CO/air flames, Combust. Flame, 2014, in press; Fig. 4, full green reverse triangle, phi = 0.7 laminar burning velocity measurement H2 CO O2 N2
x20001222.xml 10.24388/ x20001222 X. Li, X. You, F. Wu, C. K. Law, Uncertainty analysis of the kinetic model prediction for high-pressure H2/CO combustion. Proc. Combust. Inst. 2015, in press. Table 2, Exp. No.s 10a-10d laminar burning velocity measurement H2 O2 CO2
x21003001.xml 10.24388/ x21003001 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 6, cross laminar burning velocity measurement C2H5OH O2 N2
x21003002.xml 10.24388/ x21003002 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 7, cross laminar burning velocity measurement C2H5OH O2 N2
x21003003.xml 10.24388/ x21003003 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 7, asterisk laminar burning velocity measurement C2H5OH O2 N2
x21003004.xml 10.24388/ x21003004 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 8, open square laminar burning velocity measurement C2H5OH O2 N2
x21003005.xml 10.24388/ x21003005 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 8, full square laminar burning velocity measurement C2H5OH O2 N2
x21003006.xml 10.24388/ x21003006 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 8, full circle laminar burning velocity measurement C2H5OH O2 N2
x21003007.xml 10.24388/ x21003007 D. Bradley. M. Lawes, M.S. Mansour, Combust. Flame 156 (2009), 1462-1470, Fig. 8, full triangle laminar burning velocity measurement C2H5OH O2 N2
x21003008.xml 10.24388/ x21003008 E. Varea, V. Modica, A. Vandel, B. Renou, Combust. Flame 159 (2012) 577-590, Fig. 21, open circle laminar burning velocity measurement C2H5OH O2 N2
x21003009.xml 10.24388/ x21003009 E. Varea, V. Modica, A. Vandel, B. Renou, Combust. Flame 159 (2012) 577-590, Fig. 24, open circle laminar burning velocity measurement C2H5OH O2 N2
x21003010.xml 10.24388/ x21003010 S.Y. Liao, D.M. Jiang, Z.H. Huang, K. Zeng, Q. Cheng. Applied Thermal Engineering 27 (2007) 374-380, Fig. 7, full circle laminar burning velocity measurement C2H5OH O2 N2
x21003011.xml 10.24388/ x21003011 S.Y. Liao, D.M. Jiang, Z.H. Huang, K. Zeng, Q. Cheng. Applied Thermal Engineering 27 (2007) 374-380, Fig. 8, top, full diamond laminar burning velocity measurement C2H5OH O2 N2
x21003012.xml 10.24388/ x21003012 S.Y. Liao, D.M. Jiang, Z.H. Huang, K. Zeng, Q. Cheng. Applied Thermal Engineering 27 (2007) 374-380, Fig. 8, middle, full diamond laminar burning velocity measurement C2H5OH O2 N2
x21003013.xml 10.24388/ x21003013 S.Y. Liao, D.M. Jiang, Z.H. Huang, K. Zeng, Q. Cheng. Applied Thermal Engineering 27 (2007) 374-380, Fig. 8, bottom, full diamond laminar burning velocity measurement C2H5OH O2 N2
x21003014.xml 10.24388/ x21003014 T. Hara, K. Tanoue, Technical Report F2006SC40, FISITA 2006 World Automotive Congress, Yokohama, Japan. Table 1, C2H5OH/Air laminar burning velocity measurement C2H5OH O2 N2
x21003016.xml 10.24388/ x21003016 J.T. Farrell, R.J. Johnston, I.P. Androulakis, SAE Paper 2004-01-2936. Fig. 12, black full circle laminar burning velocity measurement C2H5OH O2 N2
x21003017.xml 10.24388/ x21003017 G. Broustail, P. Seers, F. Halter, G. Moreac, C. Mounaim-Rousselle; Fuel 90 (2011) 1-6, Fig. 2, full diamond laminar burning velocity measurement C2H5OH O2 N2
x21003018.xml 10.24388/ x21003018 G. Broustail, F. Halter, P. Seers, G. Moreac, C. Mounaim-Rousselle, Fuel 106 (2013) 310-317, Fig. 4, top left, open square laminar burning velocity measurement C2H5OH O2 N2
x21003019.xml 10.24388/ x21003019 G. Broustail, F. Halter, P. Seers, G. Moreac, C. Mounaim-Rousselle, Fuel 106 (2013) 310-317, Fig. 4, top right, open circle laminar burning velocity measurement C2H5OH O2 N2
x21003020.xml 10.24388/ x21003020 G. Broustail, F. Halter, P. Seers, G. Moreac, C. Mounaim-Rousselle, Fuel 106 (2013) 310-317, Fig. 4, bottom left, open circle laminar burning velocity measurement C2H5OH O2 N2
x21003021.xml 10.24388/ x21003021 G. Broustail, F. Halter, P. Seers, G. Moreac, C. Mounaim-Rousselle, Fuel 106 (2013) 310-317, Fig. 4, bottom right, open circle laminar burning velocity measurement C2H5OH O2 N2
x21003022.xml 10.24388/ x21003022 K. Ohara, M. Tsukikawa, Y. Araki, A. Hayakawa, S. Kobayashi, Y. Nagano, T. Kitagawa, Journal of the Japan Institute of Energy, 89, 1088-1094 (2010). Fig. 2, full circle laminar burning velocity measurement C2H5OH O2 N2
x21003023.xml 10.24388/ x21003023 K. Ohara, M. Tsukikawa, Y. Araki, A. Hayakawa, S. Kobayashi, Y. Nagano, T. Kitagawa, Journal of the Japan Institute of Energy, 89, 1088-1094 (2010). Fig. 2, full triangle laminar burning velocity measurement C2H5OH O2 N2
x21003024.xml 10.24388/ x21003024 K. Ohara, M. Tsukikawa, Y. Araki, A. Hayakawa, S. Kobayashi, Y. Nagano, T. Kitagawa. Journal of the Japan Institute of Energy, 89, 1088-1094 (2010). Fig. 2, full square laminar burning velocity measurement C2H5OH O2 N2
x21003025.xml 10.24388/ x21003025 S. Jerzembeck: Experimentelle und numerische Untersuchung instationaerer laminarer Flammen bei hohem Druck. Dissertation. RWTH Aachen. 2010. Fig. 4.11, full square laminar burning velocity measurement C2H5OH O2 N2
x21003026.xml 10.24388/ x21003026 E. Varea et al., Proc. Combust. Inst. 34 (2013), 735-744, Fig. 2, cross laminar burning velocity measurement C2H5OH O2 N2
x21003027.xml 10.24388/ x21003027 J. Beeckmann et al., Proc. 6th Europ. Combust. Meeting (2013), P3-76, RWTH data series @ 1 atm, 373 K for ethanol, results scaled to 20.94% O2 content of air laminar burning velocity measurement C2H5OH O2 N2
x21003028.xml 10.24388/ x21003028 J. Beeckmann et al., Proc. 6th Europ. Combust. Meeting (2013), P3-76, RWTH data series @ 5 bar, 373 K for ethanol, technical air with 20.5% O2 laminar burning velocity measurement C2H5OH O2 N2
x21003029.xml 10.24388/ x21003029 J. Beeckmann, O. Roehl, N. Peters, SAE paper 2009-01-2784, Fig. 5, full black square laminar burning velocity measurement C2H5OH O2 N2
x21003030.xml 10.24388/ x21003030 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 2, open square laminar burning velocity measurement C2H5OH O2 N2
x21003031.xml 10.24388/ x21003031 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, full square, phi=0.7 laminar burning velocity measurement C2H5OH O2 N2
x21003032.xml 10.24388/ x21003032 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, full triangle, phi=0.8 laminar burning velocity measurement C2H5OH O2 N2
x21003033.xml 10.24388/ x21003033 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, open reverse triangle, phi=0.9 laminar burning velocity measurement C2H5OH O2 N2
x21003034.xml 10.24388/ x21003034 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, open triangle, phi=1.0 laminar burning velocity measurement C2H5OH O2 N2
x21003035.xml 10.24388/ x21003035 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, open circle, phi=1.1 laminar burning velocity measurement C2H5OH O2 N2
x21003036.xml 10.24388/ x21003036 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, open square, phi=1.2 laminar burning velocity measurement C2H5OH O2 N2
x21003037.xml 10.24388/ x21003037 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 5, full circle, phi=1.3 laminar burning velocity measurement C2H5OH O2 N2
x21003038.xml 10.24388/ x21003038 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 7, middle, open square, phi=0.8 laminar burning velocity measurement C2H5OH O2 N2
x21003039.xml 10.24388/ x21003039 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 7, middle, open circle, phi=1.0 laminar burning velocity measurement C2H5OH O2 N2
x21003040.xml 10.24388/ x21003040 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 7, middle, open triangle, phi=1.2 laminar burning velocity measurement C2H5OH O2 N2
x21003041.xml 10.24388/ x21003041 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 8, middle, open square, phi=0.8 laminar burning velocity measurement C2H5OH O2 N2
x21003042.xml 10.24388/ x21003042 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 8, middle, open circle, phi=1.0 laminar burning velocity measurement C2H5OH O2 N2
x21003043.xml 10.24388/ x21003043 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 8, middle, open triangle, phi=1.2 laminar burning velocity measurement C2H5OH O2 N2
x21003044.xml 10.24388/ x21003044 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 9, middle, open square, phi=0.8 laminar burning velocity measurement C2H5OH O2 N2
x21003045.xml 10.24388/ x21003045 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 9, middle, open circle, phi=1.0 laminar burning velocity measurement C2H5OH O2 N2
x21003046.xml 10.24388/ x21003046 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281, Fig. 9, middle, open triangle, phi=1.2 laminar burning velocity measurement C2H5OH O2 N2
x21003047.xml 10.24388/ x21003047 J. Beeckmann, L. Cai, H. Pitsch, Fuel 117 (2014), 340-350, Fig. 6, full circle laminar burning velocity measurement C2H5OH O2 N2
x21003048.xml 10.24388/ x21003048 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 4 bar/ 380 K/ 0% H2O series laminar burning velocity measurement C2H5OH O2 N2
x21003049.xml 10.24388/ x21003049 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 2 bar/ 380 K/ 0% H2O series laminar burning velocity measurement C2H5OH O2 N2
x21003050.xml 10.24388/ x21003050 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 4 bar/ 450 K/ 0% H2O series laminar burning velocity measurement C2H5OH O2 N2
x21003051.xml 10.24388/ x21003051 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 2 bar/ 450 K/ 0% H2O series laminar burning velocity measurement C2H5OH O2 N2
x21003052.xml 10.24388/ x21003052 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 4 bar/ 380 K/ 20% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003053.xml 10.24388/ x21003053 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 2 bar/ 380 K/ 20% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003054.xml 10.24388/ x21003054 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 4 bar/ 450 K/ 20% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003055.xml 10.24388/ x21003055 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 2 bar/ 450 K/ 20% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003056.xml 10.24388/ x21003056 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 4 bar/ 380 K/ 40% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003057.xml 10.24388/ x21003057 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 2 bar/ 380 K/ 40% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003058.xml 10.24388/ x21003058 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 1 bar/ 380 K/ 40% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003059.xml 10.24388/ x21003059 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 4 bar/ 450 K/ 40% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003060.xml 10.24388/ x21003060 N. Hinton, R. Stone, Comparison of hydrous ethanol laminar burning velocity measurements with constant volume bomb methods, 23rd Journees d'Etude of the Belgian Section of the Combustion Institute, 28th May 2014, 2 bar/ 450 K/ 40% H2O series laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003061.xml 10.24388/ x21003061 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 318 K/ 1 bar series laminar burning velocity measurement C2H5OH O2 N2
x21003062.xml 10.24388/ x21003062 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 318 K/ 2 bar series laminar burning velocity measurement C2H5OH O2 N2
x21003063.xml 10.24388/ x21003063 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 358 K/ 1 bar series laminar burning velocity measurement C2H5OH O2 N2
x21003064.xml 10.24388/ x21003064 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 358 K/ 2 bar series laminar burning velocity measurement C2H5OH O2 N2
x21003065.xml 10.24388/ x21003065 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 373 K/ 1.013 bar series laminar burning velocity measurement C2H5OH O2 N2 Ar
x21003066.xml 10.24388/ x21003066 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 373 K/ 5 bar series laminar burning velocity measurement C2H5OH O2 N2 Ar
x21003067.xml 10.24388/ x21003067 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst. 35 (2015), 393-400; private communication with N. Chaumeix, 473 K/ 1 bar series laminar burning velocity measurement C2H5OH O2 N2
x21003068.xml 10.24388/ x21003068 J. Liang, G. Li, Z. Zhang, Z. Xiong, F. Dong, R. Yang, Energy Fuels 28 (2014), 4754-4761, Fig. 5, black square (0% H2O) laminar burning velocity measurement C2H5OH O2 N2
x21003069.xml 10.24388/ x21003069 J. Liang, G. Li, Z. Zhang, Z. Xiong, F. Dong, R. Yang, Energy Fuels 28 (2014), 4754-4761, Fig. 5, red circle (10% H2O) laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003070.xml 10.24388/ x21003070 J. Liang, G. Li, Z. Zhang, Z. Xiong, F. Dong, R. Yang, Energy Fuels 28 (2014), 4754-4761, Fig. 5, blue triangle (20% H2O) laminar burning velocity measurement C2H5OH O2 N2 H2O
x21003071.xml 10.24388/ x21003071 J. Liang, G. Li, Z. Zhang, Z. Xiong, F. Dong, R. Yang, Energy Fuels 28 (2014), 4754-4761, Fig. 5, pink reverse triangle (30% H2O) laminar burning velocity measurement C2H5OH O2 N2 H2O
x22003001.xml 10.24388/ x22003001 F.N. Egolfopoulos, D.X. Du, C.K. Law, Proc. Combust. Inst. 24 (1992), 834-841, Fig. 1 top, open triangle laminar burning velocity measurement C2H5OH O2 N2
x22003002.xml 10.24388/ x22003002 F.N. Egolfopoulos, D.X. Du, C.K. Law, Proc. Combust. Inst. 24 (1992), 834-841, Fig. 1 top, full square laminar burning velocity measurement C2H5OH O2 N2
x22003003.xml 10.24388/ x22003003 F.N. Egolfopoulos, D.X. Du, C.K. Law, Proc. Combust. Inst. 24 (1992), 834-841, Fig. 1 bottom, full triangle laminar burning velocity measurement C2H5OH O2 N2
x22003004_x.xml 10.24388/ x22003004_x F.N. Egolfopoulos, D.X. Du, C.K. Law, Proc. Combust. Inst. 24 (1992), 834-841, Fig. 1 bottom, open square laminar burning velocity measurement C2H5OH O2 N2
x22003005.xml 10.24388/ x22003005 P.S. Veloo, Y.L. Wang, F.N. Egolfopoulos, C.K. Westbrook, Combustion and Flame, 157 (2010), 1989-2004, Fig. 5, red open square laminar burning velocity measurement C2H5OH O2 N2
x23003001.xml 10.24388/ x23003001 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 298 K laminar burning velocity measurement C2H5OH O2 N2
x23003002.xml 10.24388/ x23003002 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 308 K laminar burning velocity measurement C2H5OH O2 N2
x23003003.xml 10.24388/ x23003003 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 318 K laminar burning velocity measurement C2H5OH O2 N2
x23003004.xml 10.24388/ x23003004 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 328 K laminar burning velocity measurement C2H5OH O2 N2
x23003005.xml 10.24388/ x23003005 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 338 K laminar burning velocity measurement C2H5OH O2 N2
x23003006.xml 10.24388/ x23003006 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 348 K laminar burning velocity measurement C2H5OH O2 N2
x23003007.xml 10.24388/ x23003007 A.A. Konnov, R.J. Meuwissen, L.P.H. de Goey, Proceedings of the Combustion Institute 33 (2011) 1011-1019, doi:10.1016/j.proci.2010.06.143. Table 2, 358 K laminar burning velocity measurement C2H5OH O2 N2
x23003008.xml 10.24388/ x23003008 J.P.J. van Lipzig, E.J.K. Nilsson, L.P.H. de Goey, A.A. Konnov, Fuel 90 (2011) 2773-2781, doi:10.1016/j.fuel.2011.04.029. Fig. 4, cross laminar burning velocity measurement C2H5OH O2 N2
x23003009.xml 10.24388/ x23003009 J.P.J. van Lipzig, E.J.K. Nilsson, L.P.H. de Goey, A.A. Konnov, Fuel 90 (2011) 2773-2781, doi:10.1016/j.fuel.2011.04.029. Fig. 5, cross laminar burning velocity measurement C2H5OH O2 N2
x23003013.xml 10.24388/ x23003013 P.A. Glaude, O. Herbinet, P. Dirrenberger, H. Le Gall, R. Bounaceur, F. Battin-Leclerc, A. Pires da Cruz, A.A. Konnov, ECM 2011, paper 268. Fig. 2, full blue square laminar burning velocity measurement C2H5OH O2 N2
x23003014.xml 10.24388/ x23003014 F. Rau, S. Hartl, S. Voss, C. Hasse, D. Trimis: Measurements and Numerical Study of Laminar Burning Velocities of Iso-octane and Ethanol Blends, Proceedings of the European Combustion Meeting 2013, Paper P4-77. Fig. 5, full circle laminar burning velocity measurement C2H5OH O2 N2
x23003015.xml 10.24388/ x23003015 F. Rau, S. Hartl, S. Voss, C. Hasse, D. Trimis: Measurements and Numerical Study of Laminar Burning Velocities of Iso-octane and Ethanol Blends, Proceedings of the European Combustion Meeting 2013, Paper P4-77. additional data points provided by the author laminar burning velocity measurement C2H5OH O2 N2
x23003038.xml 10.24388/ x23003038 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40, Supp. Mat. Ethanol, T = 298 K laminar burning velocity measurement C2H5OH O2 N2
x23003039.xml 10.24388/ x23003039 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40, Supp. Mat. Ethanol, T = 318 K laminar burning velocity measurement C2H5OH O2 N2
x23003040.xml 10.24388/ x23003040 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40, Supp. Mat. Ethanol, T = 328 K laminar burning velocity measurement C2H5OH O2 N2
x23003041.xml 10.24388/ x23003041 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40, Supp. Mat. Ethanol, T = 338 K laminar burning velocity measurement C2H5OH O2 N2
x23003042.xml 10.24388/ x23003042 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40, Supp. Mat. Ethanol, T = 358 K laminar burning velocity measurement C2H5OH O2 N2
x23003043.xml 10.24388/ x23003043 P. Dirrenberger, P.A. Glaude, R. Bounaceur, H. Le Gall, A. Pires da Cruz, A.A. Konnov, F. Battin-Leclerc, Fuel 115 (2014), 162-169, Supp. Mat. Ethanol, T = 298 K laminar burning velocity measurement C2H5OH O2 N2
x23003044.xml 10.24388/ x23003044 P. Dirrenberger, P.A. Glaude, R. Bounaceur, H. Le Gall, A. Pires da Cruz, A.A. Konnov, F. Battin-Leclerc, Fuel 115 (2014), 162-169, Supp. Mat. Ethanol, T = 358 K laminar burning velocity measurement C2H5OH O2 N2
x23003045.xml 10.24388/ x23003045 P. Dirrenberger, P.A. Glaude, R. Bounaceur, H. Le Gall, A. Pires da Cruz, A.A. Konnov, F. Battin-Leclerc, Fuel 115 (2014), 162-169, Supp. Mat. Ethanol, T = 398 K laminar burning velocity measurement C2H5OH O2 N2
x23003046.xml 10.24388/ x23003046 S. Voss, F. Rau, V.A. Alekseev, A.A. Konnov, R. Haas-Wittmuess, R.T.E. Hermanns, E. Volkov, L.P.H. de Goey, Proc. Europ. Combust. Meeting 2015, P3-46, Table 3 (average from three measurements: Lund, Freiberg, OWI; the uncertainties in the XML are the reported standard deviation) laminar burning velocity measurement C2H5OH O2 N2
x23003047.xml 10.24388/ x23003047 T. Knorsch, A. Zackel, D. Mamaikin, L. Zigan, M. Wensing, Energy Fuels 28 (2014) 1446-1452, Fig. 19, blue asterisk laminar burning velocity measurement C2H5OH O2 N2
x23003048.xml 10.24388/ x23003048 T. Knorsch, A. Zackel, D. Mamaikin, L. Zigan, M. Wensing, Energy Fuels 28 (2014) 1446-1452, Fig. 19, red triangle laminar burning velocity measurement C2H5OH O2 N2
x23003201.xml 10.24388/ x23003201 M. Christensen, M.T. Abebe, E.J.K. Nilsson, A.A. Konnov, Proc. Combust. Inst. 35 (2015), 499-506. Supp. Mat. T = 298 K laminar burning velocity measurement CH3CHO O2 N2
x23003202.xml 10.24388/ x23003202 M. Christensen, M.T. Abebe, E.J.K. Nilsson, A.A. Konnov, Proc. Combust. Inst. 35 (2015), 499-506. Supp. Mat. T = 318 K laminar burning velocity measurement CH3CHO O2 N2
x23003203.xml 10.24388/ x23003203 M. Christensen, M.T. Abebe, E.J.K. Nilsson, A.A. Konnov, Proc. Combust. Inst. 35 (2015), 499-506. Supp. Mat. T = 338 K laminar burning velocity measurement CH3CHO O2 N2
x23003204.xml 10.24388/ x23003204 M. Christensen, M.T. Abebe, E.J.K. Nilsson, A.A. Konnov, Proc. Combust. Inst. 35 (2015), 499-506. Supp. Mat. T = 348 K laminar burning velocity measurement CH3CHO O2 N2
x23003205.xml 10.24388/ x23003205 M. Christensen, M.T. Abebe, E.J.K. Nilsson, A.A. Konnov, Proc. Combust. Inst. 35 (2015), 499-506. Supp. Mat. T = 358 K laminar burning velocity measurement CH3CHO O2 N2
x30000010.xml 10.24388/ x30000010 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 4 concentration time profile measurement H2 O2 N2
x30000011.xml 10.24388/ x30000011 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 5a concentration time profile measurement H2 O2 N2
x30000012.xml 10.24388/ x30000012 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 5b concentration time profile measurement H2 O2 N2
x30000013.xml 10.24388/ x30000013 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 5c concentration time profile measurement H2 O2 N2
x30000014.xml 10.24388/ x30000014 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 8 concentration time profile measurement H2 O2 N2
x30000015_x.xml 10.24388/ x30000015_x Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 10a, open circle concentration time profile measurement H2 O2 N2
x30000016_x.xml 10.24388/ x30000016_x Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 10a, open square concentration time profile measurement H2 O2 N2
x30000017.xml 10.24388/ x30000017 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 10b, open circle concentration time profile measurement H2 O2 N2
x30000018.xml 10.24388/ x30000018 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 10b, open square concentration time profile measurement H2 O2 N2
x30000019.xml 10.24388/ x30000019 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 10c, open circle concentration time profile measurement H2 O2 N2
x30000020_x.xml 10.24388/ x30000020_x Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 10c, open square concentration time profile measurement H2 O2 N2
x30000021.xml 10.24388/ x30000021 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 13, open circle concentration time profile measurement H2 O2 N2
x30000022.xml 10.24388/ x30000022 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 13, open square concentration time profile measurement H2 O2 N2
x30000023.xml 10.24388/ x30000023 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 13, open triangle concentration time profile measurement H2 O2 N2
x30000024.xml 10.24388/ x30000024 Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 13, open reverse triangle concentration time profile measurement H2 O2 N2
x30000025_x.xml 10.24388/ x30000025_x Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L., Int. J. Chem. Kinet., (31), 113-125, 1999, Fig. 13, open diamond concentration time profile measurement H2 O2 N2
x30000026.xml 10.24388/ x30000026 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 11 concentration time profile measurement H2 O2 N2
x30000027.xml 10.24388/ x30000027 Hashemi, H., Christensen, J.M., Gersen, S., Glarborg, P., Proceedings of the Combustion Institute, 35, 2015, Electronic Supplement, Table S2. outlet concentration measurement H2 O2 N2
x30000028.xml 10.24388/ x30000028 Hashemi, H., Christensen, J.M., Gersen, S., Glarborg, P., Proceedings of the Combustion Institute, 35, 2015, Electronic Supplement, Table S3. outlet concentration measurement H2 O2 N2
x30000029.xml 10.24388/ x30000029 Hashemi, H., Christensen, J.M., Gersen, S., Glarborg, P., Proceedings of the Combustion Institute, 35, 2015, Electronic Supplement, Table S4. outlet concentration measurement H2 O2 N2
x30000030.xml 10.24388/ x30000030 Hashemi, H., Christensen, J.M., Gersen, S., Glarborg, P., Proceedings of the Combustion Institute, 35, 2015, Electronic Supplement, Table S5. outlet concentration measurement H2 O2 N2
x30001002.xml 10.24388/ x30001002 M. A. Mueller; R. A. Yetter; F. L. Dryer, International Journal of Chemical Kinetics 1999, 31, 705-724, Table A2 concentration time profile measurement CO O2 H2O N2
x30001003.xml 10.24388/ x30001003 M. A. Mueller; R. A. Yetter; F. L. Dryer, International Journal of Chemical Kinetics 1999, 31, 705-724, Table A2 concentration time profile measurement CO O2 H2O N2
x30001004.xml 10.24388/ x30001004 M. A. Mueller; R. A. Yetter; F. L. Dryer, International Journal of Chemical Kinetics 1999, 31, 705-724, Table A2 concentration time profile measurement CO O2 H2O N2
x30001005.xml 10.24388/ x30001005 M. A. Mueller; R. A. Yetter; F. L. Dryer, International Journal of Chemical Kinetics 1999, 31, 705-724, Table A2 concentration time profile measurement CO O2 H2O N2
x30001006.xml 10.24388/ x30001006 T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 4, open circle concentration time profile measurement CO O2 H2O N2
x30001007.xml 10.24388/ x30001007 T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 4, full circle concentration time profile measurement CO O2 H2O N2
x30001008.xml 10.24388/ x30001008 T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 6, open square concentration time profile measurement CO O2 H2O N2
x30001009.xml 10.24388/ x30001009 T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 6, full triangle concentration time profile measurement CO O2 H2O N2
x30001010.xml 10.24388/ x30001010 T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 6, full circle concentration time profile measurement CO O2 H2O N2
x30001011.xml 10.24388/ x30001011 T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 9, open circle concentration time profile measurement CO O2 H2O N2
x30001012_x.xml 10.24388/ x30001012_x T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 9, open triangle concentration time profile measurement CO O2 H2O N2
x30001013_x.xml 10.24388/ x30001013_x T. J. Kim; R. A. Yetter; F. L. Dryer, in: Proceedings of the Combustion Institute, 1994; Vol. 25, pp 759-766, Fig. 9, full triangle concentration time profile measurement CO O2 H2O N2
x30001014.xml 10.24388/ x30001014 P. Glarborg; D. Kubel; K. DamJohansen; H. M. Chiang; J. W. Bozzelli, International Journal of Chemical Kinetics 1996, 28, (10), 773-790, Fig. 6 top, set 2, open circle, CO profile measured (CO/O2/H2O/N2) outlet concentration measurement CO O2 H2O N2
x30001015.xml 10.24388/ x30001015 P. Glarborg; D. Kubel; K. DamJohansen; H. M. Chiang; J. W. Bozzelli, International Journal of Chemical Kinetics 1996, 28, (10), 773-790, Fig. 6 bottom, set 3, open circle, CO profile measured (CO/O2/H2O/N2) outlet concentration measurement CO O2 H2O N2
x30001016.xml 10.24388/ x30001016 M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 4 top, open circle, set 1a outlet concentration measurement CO O2 H2O N2
x30001017.xml 10.24388/ x30001017 M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 4 bottom, open square, set 2a outlet concentration measurement CO O2 H2O N2
x30001018.xml 10.24388/ x30001018 M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 5 top, open circle, set 3a outlet concentration measurement CO O2 H2O N2
x30001019.xml 10.24388/ x30001019 M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 5 middle, open square, set 4a outlet concentration measurement CO O2 H2O N2
x30001020.xml 10.24388/ x30001020 M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 5 bottom, open triangle, set 5a outlet concentration measurement CO O2 H2O N2
x30001021_x.xml 10.24388/ x30001021_x M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 3 top, open circle, set 6a outlet concentration measurement CO O2 H2O N2
x30001022.xml 10.24388/ x30001022 M. U. Alzueta; R. Bilbao; P. Glarborg, Combustion and Flame 2001, 127, (4), 2234-2251, Fig. 3 bottom, open square, set 7a outlet concentration measurement CO O2 H2O N2
x30001023_x.xml 10.24388/ x30001023_x TG. T. Linteris; R. A. Yetter; K. Brezinsky; F. L. Dryer, Combustion and Flame 1991, 86, (1-2), 162-170, Fig. 3 concentration time profile measurement CO O2 H2O N2
x30001024_x.xml 10.24388/ x30001024_x TG. T. Linteris; R. A. Yetter; K. Brezinsky; F. L. Dryer, Combustion and Flame 1991, 86, (1-2), 162-170, Fig. 4, full symbols concentration time profile measurement CO O2 H2O N2
x30001025_x.xml 10.24388/ x30001025_x TG. T. Linteris; R. A. Yetter; K. Brezinsky; F. L. Dryer, Combustion and Flame 1991, 86, (1-2), 162-170, Fig. 4, open symbols concentration time profile measurement CO O2 H2O N2
x30001026.xml 10.24388/ x30001026 TG. T. Linteris; R. A. Yetter; K. Brezinsky; F. L. Dryer, Combustion and Flame 1991, 86, (1-2), 162-170, Fig. 5 concentration time profile measurement CO O2 H2O N2
x30001027.xml 10.24388/ x30001027 TG. T. Linteris; R. A. Yetter; K. Brezinsky; F. L. Dryer, Combustion and Flame 1991, 86, (1-2), 162-170, Fig. 7, cross (absorption) and open square (fluorescence), conceptually belongs to x30001026.xml (Fig. 5) concentration time profile measurement CO O2 H2O N2
x30001028.xml 10.24388/ x30001028 TG. T. Linteris; R. A. Yetter; K. Brezinsky; F. L. Dryer, Combustion and Flame 1991, 86, (1-2), 162-170, Fig. 8, cross (absorption) and open square (fluorescence), conceptually belongs to x30001026.xml (Fig. 5) concentration time profile measurement CO O2 H2O N2
x30001029_x.xml 10.24388/ x30001029_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 5, CO, O2, CO2 profiles measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001030.xml 10.24388/ x30001030 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 6, up triangle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001031.xml 10.24388/ x30001031 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 6, square, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001032.xml 10.24388/ x30001032 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 6, circle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001033.xml 10.24388/ x30001033 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 6, diamond, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001034.xml 10.24388/ x30001034 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 7, circle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001035.xml 10.24388/ x30001035 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 7, square, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001036.xml 10.24388/ x30001036 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 8, asterisk, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001037_x.xml 10.24388/ x30001037_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 8, circle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001038_x.xml 10.24388/ x30001038_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 8, diamond, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001039_x.xml 10.24388/ x30001039_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 8, down triangle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001040.xml 10.24388/ x30001040 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 9, down triangle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001041_x.xml 10.24388/ x30001041_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 9, up triangle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001042_x.xml 10.24388/ x30001042_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 9, diamond, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001043_x.xml 10.24388/ x30001043_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 9, square, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001044.xml 10.24388/ x30001044 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 10, up triangle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001045.xml 10.24388/ x30001045 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 10, diamond, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001046.xml 10.24388/ x30001046 R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 10, square, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001047_x.xml 10.24388/ x30001047_x R. A. Yetter; F. L. Dryer; H. Rabitz, Combustion Science and Technology 1991, 79, 129-140, Fig. 10, circle, CO profile measured (CO/O2/H2O/N2) concentration time profile measurement CO O2 H2O N2
x30001048_x.xml 10.24388/ x30001048_x R. A. Yetter; F. L. Dryer; H. Rabitz, International Journal of Chemical Kinetics 1991, 23, 97-128, data: J. Li; Z. Zhao; A. Kazakov; M. Chaos; F. L. Dryer; J. J. J. Scire, International Journal of Chemical Kinetics 2007, 39, 109-136, Fig. 10a concentration time profile measurement CO O2 H2O N2
x30001049.xml 10.24388/ x30001049 R. A. Yetter; F. L. Dryer; H. Rabitz, International Journal of Chemical Kinetics 1991, 23, 97-128, data: J. Li; Z. Zhao; A. Kazakov; M. Chaos; F. L. Dryer; J. J. J. Scire, International Journal of Chemical Kinetics 2007, 39, 109-136, Fig. 10b concentration time profile measurement CO O2 H2O N2
x30003001.xml 10.24388/ x30003001 T.S. Norton, F.L. Dryer, Int. J. Chem. Kinet. (1992) 24, 319-344, Fig. 1 concentration time profile measurement C2H5OH O2 N2
x30003002_x.xml 10.24388/ x30003002_x T.S. Norton, F.L. Dryer, Int. J. Chem. Kinet. (1992) 24, 319-344, Fig. 2 concentration time profile measurement C2H5OH O2 N2
x30003003_x.xml 10.24388/ x30003003_x T.S. Norton, F.L. Dryer, Int. J. Chem. Kinet. (1992) 24, 319-344, Fig. 3 concentration time profile measurement C2H5OH O2 N2
x30003004.xml 10.24388/ x30003004 M.U. Alzueta, J.M. Hernandez, Energy Fuels (2002), 16, 166-171, Figs. 2-4, open circle: air excess ratio=0.73 (set 1) outlet concentration measurement C2H5OH O2 H2O N2
x30003005.xml 10.24388/ x30003005 M.U. Alzueta, J.M. Hernandez, Energy Fuels (2002), 16, 166-171, Figs. 2-4, open triangle: air excess ratio=1.13 (set 3) outlet concentration measurement C2H5OH O2 H2O N2
x30003006.xml 10.24388/ x30003006 M.U. Alzueta, J.M. Hernandez, Energy Fuels (2002), 16, 166-171, Figs. 2-4, open square: air excess ratio=35.1 (set 5) outlet concentration measurement C2H5OH O2 H2O N2
x30003007.xml 10.24388/ x30003007 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 1 and 2, asterisk, air excess ratio=0.2 outlet concentration measurement C2H2 C2H5OH O2 H2O N2
x30003008.xml 10.24388/ x30003008 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 1 and 2, full circle, air excess ratio=0.7 outlet concentration measurement C2H2 C2H5OH O2 H2O N2
x30003009.xml 10.24388/ x30003009 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 1 and 2, full square, air excess ratio=1 outlet concentration measurement C2H2 C2H5OH O2 H2O N2
x30003010.xml 10.24388/ x30003010 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 1 and 2, open diamond, air excess ratio=20 outlet concentration measurement C2H2 C2H5OH O2 H2O N2
x30003011.xml 10.24388/ x30003011 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 3 and 4, full square, C2H5OH=0ppm outlet concentration measurement C2H2 O2 H2O N2
x30003012.xml 10.24388/ x30003012 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 3 and 4, full circle, C2H5OH=50ppm outlet concentration measurement C2H2 C2H5OH O2 H2O N2
x30003013.xml 10.24388/ x30003013 M. Abian, C. Esarte, A. Millera, R. Bilbao, M.U. Alzueta, Energy Fuels (2008), 22, 3814-3823, Figs. 3 and 4, open diamond, C2H5OH=200ppm outlet concentration measurement C2H2 C2H5OH O2 H2O N2
x30003014.xml 10.24388/ x30003014 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 5 top concentration time profile measurement C2H5OH O2 N2
x30003015.xml 10.24388/ x30003015 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 5 middle concentration time profile measurement C2H5OH O2 N2
x30003016.xml 10.24388/ x30003016 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 5 bottom and Fig. 2a concentration time profile measurement C2H5OH O2 N2
x30003017.xml 10.24388/ x30003017 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 6 top concentration time profile measurement C2H5OH O2 N2
x30003018.xml 10.24388/ x30003018 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 6 middle concentration time profile measurement C2H5OH O2 N2
x30003019.xml 10.24388/ x30003019 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 6 bottom concentration time profile measurement C2H5OH O2 N2
x30003020.xml 10.24388/ x30003020 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 7 top concentration time profile measurement C2H5OH O2 N2
x30003021.xml 10.24388/ x30003021 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 7 middle and Fig. 2b concentration time profile measurement C2H5OH O2 N2
x30003022_x.xml 10.24388/ x30003022_x J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 7 bottom concentration time profile measurement C2H5OH O2 N2
x30003023.xml 10.24388/ x30003023 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 8 top concentration time profile measurement C2H5OH O2 N2
x30003024.xml 10.24388/ x30003024 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 8 middle concentration time profile measurement C2H5OH O2 N2
x30003025.xml 10.24388/ x30003025 J. Li, A. Kazakov, M. Chaos, F.L. Dryer, 5th US Combustion Meeting 2007, Paper #C26, Fig. 8 bottom concentration time profile measurement C2H5OH O2 N2
x40000001.xml 10.24388/ x40000001 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.35, 8 bar series ignition delay measurement H2 O2 Ar N2
x40000002_x.xml 10.24388/ x40000002_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.35, 16 bar series ignition delay measurement H2 O2 Ar N2
x40000003_x.xml 10.24388/ x40000003_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.35, 32 bar series ignition delay measurement H2 O2 Ar N2
x40000005_x.xml 10.24388/ x40000005_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.5, 8 bar series, 2nd series ignition delay measurement H2 O2 Ar N2
x40000006.xml 10.24388/ x40000006 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.5, 16 bar series ignition delay measurement H2 O2 Ar N2
x40000007_x.xml 10.24388/ x40000007_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.5, 32 bar series ignition delay measurement H2 O2 Ar N2
x40000008.xml 10.24388/ x40000008 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.5, 32 bar series, 2nd series ignition delay measurement H2 O2 Ar N2
x40000009.xml 10.24388/ x40000009 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 100/0, Phi = 0.5, 16 bar series, dilution experiment ignition delay measurement H2 O2 Ar N2
x40000011_1.xml 10.24388/ x40000011_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 10 bar series, point 1 ignition delay measurement H2 O2 N2
x40000011_2.xml 10.24388/ x40000011_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 10 bar series, point 2 ignition delay measurement H2 O2 N2
x40000011_3.xml 10.24388/ x40000011_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 10 bar series, point 3 ignition delay measurement H2 O2 N2
x40000011_4.xml 10.24388/ x40000011_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 10 bar series, point 4 ignition delay measurement H2 O2 N2
x40000012_1.xml 10.24388/ x40000012_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 1 ignition delay measurement H2 O2 N2
x40000012_2.xml 10.24388/ x40000012_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 2 ignition delay measurement H2 O2 N2
x40000012_3.xml 10.24388/ x40000012_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 3 ignition delay measurement H2 O2 N2
x40000012_4.xml 10.24388/ x40000012_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 4 ignition delay measurement H2 O2 N2
x40000012_5.xml 10.24388/ x40000012_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 5 ignition delay measurement H2 O2 N2
x40000012_6.xml 10.24388/ x40000012_6 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 6 ignition delay measurement H2 O2 N2
x40000012_7.xml 10.24388/ x40000012_7 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 7 ignition delay measurement H2 O2 N2
x40000012_8.xml 10.24388/ x40000012_8 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 30 bar series, point 8 ignition delay measurement H2 O2 N2
x40000013_1.xml 10.24388/ x40000013_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 1 ignition delay measurement H2 O2 N2
x40000013_2.xml 10.24388/ x40000013_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 2 ignition delay measurement H2 O2 N2
x40000013_3.xml 10.24388/ x40000013_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 3 ignition delay measurement H2 O2 N2
x40000013_4.xml 10.24388/ x40000013_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 4 ignition delay measurement H2 O2 N2
x40000013_5.xml 10.24388/ x40000013_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 5 ignition delay measurement H2 O2 N2
x40000013_6.xml 10.24388/ x40000013_6 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 6 ignition delay measurement H2 O2 N2
x40000013_7.xml 10.24388/ x40000013_7 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #1, 70 bar series, point 7 ignition delay measurement H2 O2 N2
x40000014_1.xml 10.24388/ x40000014_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 10 bar series, point 1 ignition delay measurement H2 H2O O2 N2
x40000014_2.xml 10.24388/ x40000014_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 10 bar series, point 2 ignition delay measurement H2 H2O O2 N2
x40000014_3.xml 10.24388/ x40000014_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 10 bar series, point 3 ignition delay measurement H2 H2O O2 N2
x40000014_4.xml 10.24388/ x40000014_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 10 bar series, point 4 ignition delay measurement H2 H2O O2 N2
x40000014_5.xml 10.24388/ x40000014_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 10 bar series, point 5 ignition delay measurement H2 H2O O2 N2
x40000015_1.xml 10.24388/ x40000015_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 1 ignition delay measurement H2 H2O O2 N2
x40000015_2.xml 10.24388/ x40000015_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 2 ignition delay measurement H2 H2O O2 N2
x40000015_3.xml 10.24388/ x40000015_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 3 ignition delay measurement H2 H2O O2 N2
x40000015_4.xml 10.24388/ x40000015_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 4 ignition delay measurement H2 H2O O2 N2
x40000015_5.xml 10.24388/ x40000015_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 5 ignition delay measurement H2 H2O O2 N2
x40000015_6.xml 10.24388/ x40000015_6 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 6 ignition delay measurement H2 H2O O2 N2
x40000015_7.xml 10.24388/ x40000015_7 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 7 ignition delay measurement H2 H2O O2 N2
x40000015_8.xml 10.24388/ x40000015_8 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 30 bar series, point 8 ignition delay measurement H2 H2O O2 N2
x40000016_1.xml 10.24388/ x40000016_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 1 ignition delay measurement H2 H2O O2 N2
x40000016_2.xml 10.24388/ x40000016_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 2 ignition delay measurement H2 H2O O2 N2
x40000016_3.xml 10.24388/ x40000016_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 3 ignition delay measurement H2 H2O O2 N2
x40000016_4.xml 10.24388/ x40000016_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 4 ignition delay measurement H2 H2O O2 N2
x40000016_5.xml 10.24388/ x40000016_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 5 ignition delay measurement H2 H2O O2 N2
x40000016_6.xml 10.24388/ x40000016_6 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 6 ignition delay measurement H2 H2O O2 N2
x40000016_7.xml 10.24388/ x40000016_7 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #2, 70 bar series, point 7 ignition delay measurement H2 H2O O2 N2
x40000017_1.xml 10.24388/ x40000017_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 30 bar series, point 1 ignition delay measurement H2 H2O O2 N2
x40000017_2.xml 10.24388/ x40000017_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 30 bar series, point 2 ignition delay measurement H2 H2O O2 N2
x40000017_3.xml 10.24388/ x40000017_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 30 bar series, point 3 ignition delay measurement H2 H2O O2 N2
x40000017_4.xml 10.24388/ x40000017_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 30 bar series, point 4 ignition delay measurement H2 H2O O2 N2
x40000017_5.xml 10.24388/ x40000017_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 30 bar series, point 5 ignition delay measurement H2 H2O O2 N2
x40000017_6.xml 10.24388/ x40000017_6 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 30 bar series, point 6 ignition delay measurement H2 H2O O2 N2
x40000018_1.xml 10.24388/ x40000018_1 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 70 bar series, point 1 ignition delay measurement H2 H2O O2 N2
x40000018_2.xml 10.24388/ x40000018_2 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 70 bar series, point 2 ignition delay measurement H2 H2O O2 N2
x40000018_3.xml 10.24388/ x40000018_3 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 70 bar series, point 3 ignition delay measurement H2 H2O O2 N2
x40000018_4.xml 10.24388/ x40000018_4 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 70 bar series, point 4 ignition delay measurement H2 H2O O2 N2
x40000018_5.xml 10.24388/ x40000018_5 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 70 bar series, point 5 ignition delay measurement H2 H2O O2 N2
x40000018_6.xml 10.24388/ x40000018_6 A. K. Das, C.-J. Sung, Y. Zhang, G. Mittal, Int. J. Hydrogen Energy 38 (2012) 6901-6911, Mixture #3, 70 bar series, point 6 ignition delay measurement H2 H2O O2 N2
x40001002_1.xml 10.24388/ x40001002_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open circle ignition delay measurement H2 O2 N2 Ar
x40001002_2.xml 10.24388/ x40001002_2 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open circle ignition delay measurement H2 O2 N2 Ar
x40001002_4.xml 10.24388/ x40001002_4 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open circle ignition delay measurement H2 O2 N2 Ar
x40001002_5.xml 10.24388/ x40001002_5 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open circle ignition delay measurement H2 O2 N2 Ar
x40001003_1.xml 10.24388/ x40001003_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open square, point 1 ignition delay measurement CO H2 O2 N2 Ar
x40001004_1.xml 10.24388/ x40001004_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open diamond, point 1 ignition delay measurement CO H2 O2 N2 Ar
x40001005_1.xml 10.24388/ x40001005_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open triangle, point 1 ignition delay measurement CO H2 O2 N2 Ar
x40001006_1.xml 10.24388/ x40001006_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 6, open reverse triangle, point 1 ignition delay measurement CO H2 O2 N2 Ar
x40001007_1.xml 10.24388/ x40001007_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open circle ignition delay measurement H2 O2 N2 Ar
x40001007_3.xml 10.24388/ x40001007_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open circle ignition delay measurement H2 O2 N2 Ar
x40001007_5.xml 10.24388/ x40001007_5 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open circle ignition delay measurement H2 O2 N2 Ar
x40001007_6.xml 10.24388/ x40001007_6 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open circle ignition delay measurement H2 O2 N2 Ar
x40001008_3.xml 10.24388/ x40001008_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open square, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001009_3.xml 10.24388/ x40001009_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open diamond, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001010_3.xml 10.24388/ x40001010_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open triangle, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001011_3.xml 10.24388/ x40001011_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 7, open reverse triangle, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001012_1.xml 10.24388/ x40001012_1 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open circle ignition delay measurement H2 O2 N2 Ar
x40001012_3.xml 10.24388/ x40001012_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open circle ignition delay measurement H2 O2 N2 Ar
x40001012_5.xml 10.24388/ x40001012_5 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open circle ignition delay measurement H2 O2 N2 Ar
x40001012_6.xml 10.24388/ x40001012_6 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open circle ignition delay measurement H2 O2 N2 Ar
x40001013_3.xml 10.24388/ x40001013_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open square, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001014_3.xml 10.24388/ x40001014_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open diamond, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001015_3.xml 10.24388/ x40001015_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open triangle, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001016_3.xml 10.24388/ x40001016_3 G. Mittal; C. J. Sung; R. A. Yetter, International Journal of Chemical Kinetics 2006, 38, 516-529, Fig. 8, open reverse triangle, point 3 ignition delay measurement CO H2 O2 N2 Ar
x40001031.xml 10.24388/ x40001031 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.35, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001032_x.xml 10.24388/ x40001032_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.35, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001033.xml 10.24388/ x40001033 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.35, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001034.xml 10.24388/ x40001034 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.5, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001035.xml 10.24388/ x40001035 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.5, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001036.xml 10.24388/ x40001036 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.5, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001037.xml 10.24388/ x40001037 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 85/15, Phi = 0.5, 16 bar series, dilution experiment ignition delay measurement H2 CO O2 N2 Ar
x40001038.xml 10.24388/ x40001038 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.35, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001039.xml 10.24388/ x40001039 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.35, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001040.xml 10.24388/ x40001040 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.35, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001041.xml 10.24388/ x40001041 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.5, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001042.xml 10.24388/ x40001042 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.5, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001043.xml 10.24388/ x40001043 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.5, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001044.xml 10.24388/ x40001044 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 50/50, Phi = 0.5, 16 bar series, dilution experiment ignition delay measurement H2 CO O2 N2 Ar
x40001045.xml 10.24388/ x40001045 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 25/75, Phi = 0.35, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001046.xml 10.24388/ x40001046 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 25/75, Phi = 0.35, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001047.xml 10.24388/ x40001047 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 25/75, Phi = 0.35, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001048.xml 10.24388/ x40001048 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 25/75, Phi = 0.5, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001049.xml 10.24388/ x40001049 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 25/75, Phi = 0.5, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001050.xml 10.24388/ x40001050 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 25/75, Phi = 0.5, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001051_x.xml 10.24388/ x40001051_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 5/95, Phi = 0.35, 6 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001052.xml 10.24388/ x40001052 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 5/95, Phi = 0.35, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001053.xml 10.24388/ x40001053 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 5/95, Phi = 0.35, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001054_x.xml 10.24388/ x40001054_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 5/95, Phi = 0.5, 8 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001055.xml 10.24388/ x40001055 A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 5/95, Phi = 0.5, 16 bar series ignition delay measurement H2 CO O2 N2 Ar
x40001056_x.xml 10.24388/ x40001056_x A. Keromnes; W. K. Metcalfe; K. Heufer; H. J. Curran; N. Donohoe; A. K. Das; C. J. Sung; J. Herzler; C. Naumann; P. Griebel; O. Mathieu; M. C. Krejci; E. Petersen; W. J. Pitz; H. J. Curran, Combustion and Flame 2012, submitted, H2/CO = 5/95, Phi = 0.5, 32 bar series ignition delay measurement H2 CO O2 N2 Ar
x40003002_1.xml 10.24388/ x40003002_1 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 10 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003002_2.xml 10.24388/ x40003002_2 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 10 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003002_3.xml 10.24388/ x40003002_3 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 10 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003002_4.xml 10.24388/ x40003002_4 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 10 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003002_5.xml 10.24388/ x40003002_5 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 10 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_1.xml 10.24388/ x40003003_1 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_2.xml 10.24388/ x40003003_2 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_3.xml 10.24388/ x40003003_3 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_4.xml 10.24388/ x40003003_4 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_5.xml 10.24388/ x40003003_5 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_6.xml 10.24388/ x40003003_6 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_7.xml 10.24388/ x40003003_7 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003003_8.xml 10.24388/ x40003003_8 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 25 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_1.xml 10.24388/ x40003004_1 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_2.xml 10.24388/ x40003004_2 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_3.xml 10.24388/ x40003004_3 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_4.xml 10.24388/ x40003004_4 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_5.xml 10.24388/ x40003004_5 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_6.xml 10.24388/ x40003004_6 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x40003004_7.xml 10.24388/ x40003004_7 G. Mittal, S.M. Burke, V.A. Davies, B. Parajuli, W.K. Metcalfe, H.J. Curran; Combust. Flame 161 (2014), 1164-1171, Phi = 0.3, 50 bar series ignition delay measurement C2H5OH O2 N2 Ar
x50001001.xml 10.24388/ x50001001 R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S1 outlet concentration measurement H2 CO O2 Ar
x50001002_x.xml 10.24388/ x50001002_x R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S2 outlet concentration measurement H2 CO O2 Ar
x50001003.xml 10.24388/ x50001003 R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S3 outlet concentration measurement H2 CO O2 Ar
x50001004.xml 10.24388/ x50001004 R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S4 outlet concentration measurement H2 CO O2 Ar
x50001005.xml 10.24388/ x50001005 R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S5 outlet concentration measurement H2 CO O2 Ar
x50001006.xml 10.24388/ x50001006 R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S6 outlet concentration measurement H2 CO O2 Ar
x50001007.xml 10.24388/ x50001007 R. Sivaramakrishnan; A. Comandini; R. S. Tranter; K. Brezinsky; S. G. Davis; H. Wang, Proceedings of the Combustion Institute 2007, 31, (1), 429-437, Supplemental Material, Table S7 outlet concentration measurement H2 CO O2 Ar
x50003001.xml 10.24388/ x50003001 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst., 35, 2015, Fig. 1 concentration time profile measurement C2H5OH Ar Ne
x50003002.xml 10.24388/ x50003002 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst., 35, 2015, Fig. 2a concentration time profile measurement C2H5OH O2 Ar Ne
x50003003.xml 10.24388/ x50003003 M. Aghsaee, D. Nativel, M. Bozkurt, M. Fikri, N. Chaumeix, C. Schulz, Proc. Combust. Inst., 35, 2015, Fig. 2a concentration time profile measurement C2H5OH O2 Ar Ne
x50003004.xml 10.24388/ x50003004 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1242 K series concentration time profile measurement Ne C2H5OH Kr
x50003005.xml 10.24388/ x50003005 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1302 K series concentration time profile measurement Ne C2H5OH Kr
x50003006.xml 10.24388/ x50003006 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1324 K series concentration time profile measurement Ne C2H5OH Kr
x50003007.xml 10.24388/ x50003007 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1342 K series concentration time profile measurement Ne C2H5OH Kr
x50003008.xml 10.24388/ x50003008 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1384 K series concentration time profile measurement Ne C2H5OH Kr
x50003009.xml 10.24388/ x50003009 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1396 K series concentration time profile measurement Ne C2H5OH Kr
x50003010.xml 10.24388/ x50003010 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1420 K series concentration time profile measurement Ne C2H5OH Kr
x50003011.xml 10.24388/ x50003011 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1430 K series concentration time profile measurement Ne C2H5OH Kr
x50003012.xml 10.24388/ x50003012 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1452 K series concentration time profile measurement Ne C2H5OH Kr
x50003013.xml 10.24388/ x50003013 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1490 K series concentration time profile measurement Ne C2H5OH Kr
x50003014.xml 10.24388/ x50003014 J. Kiecherer, C. Baensch, T. Bentz, M. Olzmann, Proc. Combust. Inst., 35, 2015, 465-472, data obtained from author, 1490 K series concentration time profile measurement Ne C2H5OH Kr
k00000085.xml 10.24388/ k00000085 D. Stone, D.M. Rowley, Phys. Chem. Chem. Phys. 4 (2002) 4392-4398 Rate coefficient determination - HO2+HO2=H2O2+O2  
k00000086.xml 10.24388/ k00000086 N. Kanno, K. Tonokura, M. Koshi, J. Geophys. Res. Atmos. 111 (2006) D20312 Rate coefficient determination - HO2+HO2=H2O2+O2  
k00000087.xml 10.24388/ k00000087 O. Dobis, S.W. Benson, J. Am. Chem. Soc. 115 (1993) 8798-8809 Rate coefficient determination - HO2+HO2=H2O2+O2  
k00000088.xml 10.24388/ k00000088 R. Patrick, M.J. Pilling, Chem. Phys. Lett. 91 (1982) 343-347 Rate coefficient determination - HO2+HO2=H2O2+O2  
k00000089.xml 10.24388/ k00000089 J.P. Burrows, R.A. Cox, R.G. Derwent, J. Photochem. 16 (1981) 147-168 Rate coefficient determination - HO2+HO2=H2O2+O2  
k00000090.xml 10.24388/ k00000090 R.-R. Lii, R.A. Gorse Jr., M.C. Sauer Jr., S. Gordon, J. Phys. Chem. 83 (1979) 1803-1804, Rate coefficient determination - HO2+HO2=H2O2+O2  
k10002001.xml 10.24388/ k10002001 L.T. Zaczek, K.Y. Lam, D.F. Davidson, R.K. Hanson, Proc. Combust. Inst. 35 (2015), 377-384 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k10002002.xml 10.24388/ k10002002 E. Jimenez, M.K. Gilles, A.R. Ravishankara, J. Photochem. Photobiol. A 157 (2003), 237-245 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k10002003.xml 10.24388/ k10002003 W. P. Hess, F.P. Tully, J. Phys. Chem. 93 (1989), 1944-1947 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k10002004.xml 10.24388/ k10002004 T.J. Dillon, D. Hoelscher, V. Sivakumaran, A. Horowitz, J.N. Crowley, Phys. Chem. Chem. Phys. 7 (2005), 349-355 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k10002005.xml 10.24388/ k10002005 N.K. Srinivasan, M.-C. Su, J.V. Michael, J. Phys. Chem. A 111 (2007) 3951-3958 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k10002006.xml 10.24388/ k10002006 J.F. Bott, N. Cohen, Int. J. Chem. Kinet. 23 (1991), 1075-1094 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k10002007.xml 10.24388/ k10002007 T.J. Wallington, M.J. Kurylo, Int. J. Chem. Kinet. 19 (1987), 1015-1023 Rate coefficient determination - CH3OH+OH=PRODUCTS  
k11002004.xml 10.24388/ k11002004 Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 Rate coefficient determination - LPCH2O+M=PRODUCTS CH2O Ar
k11002014.xml 10.24388/ k11002014 S.S. Kumaran, J.J. Carroll, J.V. Michael, Proc. Combust. Inst. 23 (1998), 125-133 Rate coefficient determination - LPCH2O+M=HCO+H+M  
k11002015.xml 10.24388/ k11002015 S.S. Kumaran, J.J. Carroll, J.V. Michael, Proc. Combust. Inst. 23 (1998), 125-133 Rate coefficient determination - LPCH2O+M=CO+H2+M  
k11002021.xml 10.24388/ k11002021 V. Vasudevan, D.F. Davidson, R.K. Hanson, C.T. Bowman, D.M. Golden, Proc. Combust. Inst. 31 (2007) 175-183 Rate coefficient determination - LPCH2O+M=HCO+H+M O2 Ar
k11002022.xml 10.24388/ k11002022 V. Vasudevan, D.F. Davidson, R.K. Hanson, C.T. Bowman, D.M. Golden, Proc. Combust. Inst. 31 (2007) 175-183 Rate coefficient determination - LPCH2O+M=CO+H2+M O2 Ar
k12002001.xml 10.24388/ k12002001 A.A. Jemi-Alade, P.D. Lightfoot, R. Lesclaux, Chem. Phys. Lett. 195 (1992) 25-30 Rate coefficient determination - CH2O+HO2=HCO+H2O2  
k13002002.xml 10.24388/ k13002002 R. De Avillez Pereira, D.L. Baulch, M.J. Pilling, S.H. Robertson, G. Zeng, J. Phys. Chem A 101 (1998) 9681-9693 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002003.xml 10.24388/ k13002003 R. De Avillez Pereira, D.L. Baulch, M.J. Pilling, S.H. Robertson, G. Zeng, J. Phys. Chem A 101 (1998) 9681-9693 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002004.xml 10.24388/ k13002004 R. De Avillez Pereira, D.L. Baulch, M.J. Pilling, S.H. Robertson, G. Zeng, J. Phys. Chem A 101 (1998) 9681-9693 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002005.xml 10.24388/ k13002005 V. Vasudevan, R.D. Cook, R.K. Hanson, C.T. Bowman, D.M. Golden, Int. J. Chem. Kinet. 40 (2008), 488-495 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002006.xml 10.24388/ k13002006 R. Deters, H.Gg. Wagner, A. Bencsura, K. Imrik, S. Dobe, T. Berces, F. Marta, F. Temps, T. Turanyi, I.Gy. Zsely, Proc. 3rd Europ. Combust. Meeting (2003), Paper 21 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002007.xml 10.24388/ k13002007 S. Wang, S. Li, D.F. Davidson, R.K. Hanson, J. Phys. Chem. A 119 (2015) 8799-8805 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002008.xml 10.24388/ k13002008 L.N. Krasnoperov, J.V. Michael, J. Phys. Chem. A 108 (2004), 8317-8323 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002009.xml 10.24388/ k13002009 J.F. Bott, N. Cohen, Int. J. Chem. Kinet. 23 (1991), 1017-1033 Rate coefficient determination - CH3+OH=PRODUCTS  
k13002010.xml 10.24388/ k13002010 M. Sangwan, E.N. Chesnokov, L.N. Krasnoperov, J. Phys. Chem. A (116) 8661-8670 Rate coefficient determination - CH3+OH=PRODUCTS  
k14002001.xml 10.24388/ k14002001 G. Friedrichs, D.F. Davidson, R.K. Hanson, Int. J. Chem. Kinet. 34 (2002) 374-386 Rate coefficient determination - CH2O+H=HCO+H2  
k14002002.xml 10.24388/ k14002002 C. Oehlers, H. Gg. Wagner, H. Ziemer, F. Temps, S. Dobe, J. Phys. Chem. A 104 (2000), 10500-10510 Rate coefficient determination - CH2O+H=HCO+H2  
k14002003.xml 10.24388/ k14002003 T.K. Choudhury, M.C. Lin, Combust. Sci. Technol. 64 (1989), 19-28 Rate coefficient determination - CH2O+H=HCO+H2  
k14002004.xml 10.24388/ k14002004 R.B. Klemm, J. Chem. Phys. 71 (1979), 1987-1993 Rate coefficient determination - CH2O+H=HCO+H2  
k14002005.xml 10.24388/ k14002005 A.M. Dean, B.L. Craig, R.L. Johnson, M.C. Schultz, E.E. Wang, Proc. Combust. Inst. 17 (1979), 577-586 Rate coefficient determination - CH2O+H=HCO+H2  
k14002006.xml 10.24388/ k14002006 A.A. Westenberg, N. deHaas, J. Phys. Chem. 76 (1972), 2213-2214 Rate coefficient determination - CH2O+H=HCO+H2  
k14002007.xml 10.24388/ k14002007 S. Wang, E.E. Dames, D.F. Davidson, R.K. Hanson, J. Phys. Chem A. 118 (2014), 10201-10209, Table 2 Rate coefficient determination - CH2O+H=HCO+H2  
k14002008.xml 10.24388/ k14002008 E.A. Irdam, J.H. Kiefer, L.B. Harding, A.F. Wagner, Int. J. Chem. Kinet. 25 (1993), 285-303 Rate coefficient determination - CH2O+H=HCO+H2  
k20002001.xml 10.24388/ k20002001 J.F. Meagher, P. Kim, J.H. Lee, R.B. Timmons, J. Phys. Chem. 78 (1974), 2650-2657 Rate coefficient determination - CH3OH+H=PRODUCTS  
k30002001.xml 10.24388/ k30002001 T.K. Choudhury, Y. He, W.A. Sanders, M.C. Lin, J. Phys. Chem. 94 (1990), 2394-2398 Rate coefficient determination - LPCH3O+M=H+CH2O+M  
k30002002.xml 10.24388/ k30002002 T.K. Choudhury, Y. He, W.A. Sanders, M.C. Lin, J. Phys. Chem. 94 (1990), 2394-2398 Rate coefficient determination - LPCH3O+M=H+CH2O+M  
k40002001.xml 10.24388/ k40002001 N.K. Srinivasan, M.-C. Su, J.V. Michael, J. Phys. Chem. A 111 (2007) 3951-3958 Rate coefficient determination - LPCH3OH(+M)=PRODUCTS  
k40002002.xml 10.24388/ k40002002 K. Spindler, H.Gg. Wagner, Ber. Bunsenges. Phys. Chem. 86 (1982), 2-13 Rate coefficient determination - CH3OH=PRODUCTS  
k40002003.xml 10.24388/ k40002003 K. Spindler, H.Gg. Wagner, Ber. Bunsenges. Phys. Chem. 86 (1982), 2-13 Rate coefficient determination - CH3OH=PRODUCTS  
k40002004.xml 10.24388/ k40002004 K. Spindler, H.Gg. Wagner, Ber. Bunsenges. Phys. Chem. 86 (1982), 2-13 Rate coefficient determination - CH3OH=PRODUCTS  
k40002005.xml 10.24388/ k40002005 L.N. Krasnoperov, J.V. Michael, J. Phys. Chem. A 108 (2004), 8317-8323 Rate coefficient determination - LPCH3OH(+M)=CH3+OH(+M)  
k40002006.xml 10.24388/ k40002006 V. Vasudevan, R.D. Cook, R.K. Hanson, C.T. Bowman, D.M. Golden, Int. J. Chem. Kinet. 40 (2008), 488-495 Rate coefficient determination - LPCH3OH(+M)=CH3+OH(+M)  
k40002007.xml 10.24388/ k40002007 K.-W. Lu, H. Matsui, C.-L. Huang, P. Raghunath, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 114 (2010), 5493-5502 Rate coefficient determination - LPCH3OH(+M)=PRODUCTS  
k40002008.xml 10.24388/ k40002008 T. Koike, M. Kudo, I. Maeda, H. Yamada, Int. J. Chem. Kinet. 32 (2000), 1-16 Rate coefficient determination - LPCH3OH(+M)=CH3+OH(+M)  
k40002008.xml 10.24388/ k40002008 T. Koike, M. Kudo, I. Maeda, H. Yamada, Int. J. Chem. Kinet. 32 (2000), 1-16 Rate coefficient determination - LPCH3OH(+M)=CH3+OH(+M)  
k40002009.xml 10.24388/ k40002009 T. Koike, M. Kudo, I. Maeda, H. Yamada, Int. J. Chem. Kinet. 32 (2000), 1-16 Rate coefficient determination - LPCH3OH(+M)=CH3+OH(+M)  
k40002010.xml 10.24388/ k40002010 P.H. Cribb, J.E. Dove, S. Yamazaki, Proc. Combust. Inst. 20 (1984), 779-787 Rate coefficient determination - LPCH3OH(+M)=PRODUCTS CH3OH Ar He
k40002011.xml 10.24388/ k40002011 P.H. Cribb, J.E. Dove, S. Yamazaki, Proc. Combust. Inst. 20 (1984), 779-787 Rate coefficient determination - LPCH3OH(+M)=PRODUCTS  
k60002001.xml 10.24388/ k60002001 A. Schocker, M. Uetake, N. Kanno, M. Koshi, K. Tonokura, J. Phys. Chem. A 111 (2007), 6622-6627 Rate coefficient determination - CH2OH+O2=CH2O+HO2  
k60002002.xml 10.24388/ k60002002 H.-H. Grotheer, G. Riekert, D. Walter, T. Just, J. Phys. Chem. 92 (1988), 4028-4030 Rate coefficient determination - CH2OH+O2=CH2O+HO2  
k70002001.xml 10.24388/ k70002001 Z. Hong, D.F. Davidson, K.-Y. Lam, R.K. Hanson, Combust. Flame 159 (2012), 3007-3013 Rate coefficient determination - CH3+HO2=CH4+O2  
k70002002.xml 10.24388/ k70002002 J.J. Scire Jr., R.A. Yetter, Frederick L. Dryer, Int. J. Chem. Kinet. 33 (2001), 75-100 Rate coefficient determination - CH3+HO2=CH4+O2  
k70002101.xml 10.24388/ k70002101 N.K. Srinivasan, J.V. Michael, L.B. Harding, S.J. Klippenstein, Combust. Flame 149 (2007), 104-111 Rate coefficient determination - CH4+O2=CH3+HO2  
k80002001.xml 10.24388/ k80002001 S. Wang, D.F. Davidson, R.K. Hanson, Proc. Combust. Inst. 35 (2015), 473-480 Rate coefficient determination - CH2O+OH=PRODUCTS  
k80002002.xml 10.24388/ k80002002 V. Vasudevan, D.F. Davidson, R.K. Hanson, Int. J. Chem. Kinet. 37 (2005), 98-109 Rate coefficient determination - CH2O+OH=HCO+H2O  
k80002003.xml 10.24388/ k80002003 J.F. Bott, N. Cohen, Int. J. Chem. Kinet. 23 (1991), 1075-1094 Rate coefficient determination - CH2O+OH=PRODUCTS  
k80002004.xml 10.24388/ k80002004 R. Atkinson, J.N. Pitts Jr., J. Chem. Phys. 68 (1978), 3581-3584 Rate coefficient determination - CH2O+OH=PRODUCTS  
k80002005.xml 10.24388/ k80002005 V. Sivakumaran, D. Hoelscher, T.J. Dillon, J.N. Crowley, Phys. Chem. Chem. Phys. 5 (2003), 4821-4827 Rate coefficient determination - CH2O+OH=HCO+H2O  
k80002006.xml 10.24388/ k80002006 S. Zabarnick. J.W. Fleming, M.C. Lin, Int. J. Chem. Kinet. 20 (1988), 117-129 Rate coefficient determination - CH2O+OH=HCO+H2O  
k90002001.xml 10.24388/ k90002001 N.K. Srinivasan, M.C. Su, J.W. Sutherland, J.V. Michael, J. Phys. Chem. A 109 (2005), 7902-7914 Rate coefficient determination - CH2O+O2=HCO+HO2  
k90002002.xml 10.24388/ k90002002 N.K. Srinivasan, M.C. Su, J.W. Sutherland, J.V. Michael, J. Phys. Chem. A 109 (2005), 7902-7914 Rate coefficient determination - CH2O+O2=HCO+HO2  
k90002003.xml 10.24388/ k90002003 V. Vasudevan, D.F. Davidson, R.K. Hanson, C.T. Bowman, D.M. Golden, Proc. Combust. Inst. 31 (2007) 175-183 Rate coefficient determination - CH2O+O2=HCO+HO2  
t00000053.xml 10.24388/ t00000053 D.D.Y. Zhou, K. Han, P. Zhang, L.B. Harding, M.J. Davis, R.T. Skodje, J. Phys. Chem. A 116 (2012), 2089-2100 Rate coefficient determination - HO2+HO2=H2O2+O2  
t10002001.xml 10.24388/ t10002001 J.T. Jodkowski, M.-T. Rayez, J.-C. Rayez, T. Berces, S. Dobe, J. Phys. Chem. A 103 (1999), 3750-3765 Rate coefficient determination - CH3OH+OH=CH3O+H2O  
t10002002.xml 10.24388/ t10002002 J.T. Jodkowski, M.-T. Rayez, J.-C. Rayez, T. Berces, S. Dobe, J. Phys. Chem. A 103 (1999), 3750-3765 Rate coefficient determination - CH3OH+OH=CH2OH+H2O  
t10002003.xml 10.24388/ t10002003 S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166 Rate coefficient determination - CH3OH+OH=CH2OH+H2O  
t10002004.xml 10.24388/ t10002004 S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166 Rate coefficient determination - CH3OH+OH=CH3O+H2O  
t11002001.xml 10.24388/ t11002001 J. Troe, J. Phys. Chem. A 111 (2007), 3862-3867 Rate coefficient determination - LPCH2O+M=CO+H2+M  
t11002002.xml 10.24388/ t11002002 J. Troe, J. Phys. Chem. A 111 (2007), 3862-3867 Rate coefficient determination - LPCH2O+M=HCO+H+M  
t11002003.xml 10.24388/ t11002003 G. Friedrichs, D.F. Davidson, R.K. Hanson, Int. J. Chem. Kinet. 36 (2004) 157-169 Rate coefficient determination - LPCH2O+M=HCO+H+M  
t11002004.xml 10.24388/ t11002004 G. Friedrichs, D.F. Davidson, R.K. Hanson, Int. J. Chem. Kinet. 36 (2004) 157-169 Rate coefficient determination - LPCH2O+M=CO+H2+M  
t12002001.xml 10.24388/ t12002001 Q.S. Li, X. Zhang, and S.W. Zhang, J. Phys. Chem. A 109 (2005), 12027-12035 Rate coefficient determination - CH2O+HO2=HCO+H2O2  
t13002002.xml 10.24388/ t13002002 A.W. Jasper, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 111 (2007) 3932-3950 Rate coefficient determination - LPOH+CH3(+M)=CH3OH(+M)  
t13002003.xml 10.24388/ t13002003 A.W. Jasper, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 111 (2007) 3932-3950 Rate coefficient determination - HPOH+CH3(+M)=CH3OH(+M)  
t14002001.xml 10.24388/ t14002001 S. Wang, E.E. Dames, D.F. Davidson, R.K. Hanson, J. Phys. Chem A. 118 (2014), 10201-10209 Rate coefficient determination - CH2O+H=HCO+H2  
t14002002.xml 10.24388/ t14002002 E.A. Irdam, J.H. Kiefer, L.B. Harding, A.F. Wagner, Int. J. Chem. Kinet. 25 (1993), 285-303 Rate coefficient determination - CH2O+H=HCO+H2  
t15002001.xml 10.24388/ t15002001 S.J. Klippenstein, L.B. Harding, M.J. Davis, A.S. Tomlin, R.T. Skodje, Proc. Combust. Inst. 33 (2011), 351-357 Rate coefficient determination - CH3OH+HO2=CH2OH+H2O2  
t15002002.xml 10.24388/ t15002002 S.J. Klippenstein, L.B. Harding, M.J. Davis, A.S. Tomlin, R.T. Skodje, Proc. Combust. Inst. 33 (2011), 351-357 Rate coefficient determination - CH3OH+HO2=CH3O+H2O2  
t15002003.xml 10.24388/ t15002003 I.M. Alecu, D.G. Truhlar, J. Phys. Chem. A 115 (2011), 14599-14611 Rate coefficient determination - CH3OH+HO2=CH2OH+H2O2  
t15002004.xml 10.24388/ t15002004 I.M. Alecu, D.G. Truhlar, J. Phys. Chem. A 115 (2011), 14599-14611 Rate coefficient determination - CH3OH+HO2=CH3O+H2O2  
t15002005.xml 10.24388/ t15002005 M. Altarawneh, A.H. Al-Muhtaseb, B.Z. Dlugogorski, E.M. Kennedy, J.C. Mackie, J. Comp. Chem. 32 (2011), 1725-1733 Rate coefficient determination - CH3OH+HO2=CH2OH+H2O2  
t15002006.xml 10.24388/ t15002006 M. Altarawneh, A.H. Al-Muhtaseb, B.Z. Dlugogorski, E.M. Kennedy, J.C. Mackie, J. Comp. Chem. 32 (2011), 1725-1733 Rate coefficient determination - CH3OH+HO2=CH3O+H2O2  
t16002001.xml 10.24388/ t16002001 S.J. Klippenstein, L.B. Harding, M.J. Davis, A.S. Tomlin, R.T. Skodje, Proc. Combust. Inst. 33 (2011), 351-357 Rate coefficient determination - CH3OH+O2=CH2OH+HO2  
t16002002.xml 10.24388/ t16002002 H. Abou-Rachid, K. El Marrouni, S. Kaliaguine, J. Molec. Struct. (Theochem) 631 (2003) 241-250 Rate coefficient determination - CH3OH+O2=PRODUCTS  
t17002001.xml 10.24388/ t17002001 E.E. Dames, D.M. Golden, J. Phys. Chem. A 117 (2013), 7686-7696 Rate coefficient determination - LPCH2OH(+M)=H+CH2O(+M)  
t20002001.xml 10.24388/ t20002001 Meana-Paneda, D.G. Truhlar, A. Fernandez-Ramos, J. Chem. Phys. 134 (2011), 094302 Rate coefficient determination - CH3OH+H=CH2OH+H2  
t20002002.xml 10.24388/ t20002002 Meana-Paneda, D.G. Truhlar, A. Fernandez-Ramos, J. Chem. Phys. 134 (2011), 094302 Rate coefficient determination - CH3OH+H=CH3O+H2  
t20002003.xml 10.24388/ t20002003 E.F.V. Carvalho, A.N. Barauna, F.B.C. Machado, O. Roberto-Neto, Chem. Phys. Lett. 463 (2008) 33-37 Rate coefficient determination - CH3OH+H=CH2OH+H2  
t20002004.xml 10.24388/ t20002004 B. Kerkeni, D.C. Clary, J. Chem. Phys. 121 (2004), 6809 Rate coefficient determination - CH3OH+H=CH2OH+H2  
t20002005.xml 10.24388/ t20002005 B. Kerkeni, D.C. Clary, J. Chem. Phys. 121 (2004), 6809 Rate coefficient determination - CH3OH+H=CH3O+H2  
t20002006.xml 10.24388/ t20002006 J.T. Jodkowski, M.-T. Rayez, J.-C. Rayez, T. Berces, S. Dobe, J. Phys. Chem. A 103 (1999), 3750-3765 Rate coefficient determination - CH3OH+H=CH3O+H2  
t20002007.xml 10.24388/ t20002007 J.T. Jodkowski, M.-T. Rayez, J.-C. Rayez, T. Berces, S. Dobe, J. Phys. Chem. A 103 (1999), 3750-3765 Rate coefficient determination - CH3OH+H=CH2OH+H2  
t30002001.xml 10.24388/ t30002001 H. Hippler, F. Striebel, B. Viskolcz, Phys. Chem. Chem. Phys. 3 (2001), 2450-2458 Rate coefficient determination - LPCH3O(+M)=H+CH2O(+M)  
t30002006.xml 10.24388/ t30002006 E.E. Dames, D.M. Golden, J. Phys. Chem. A 117 (2013), 7686-7696 Rate coefficient determination - LPCH3O(+M)=H+CH2O(+M)  
t40002001.xml 10.24388/ t40002001 A.W. Jasper, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 111 (2007) 3932-3950 Rate coefficient determination - LPCH3OH(+M)=OH+CH3(+M)  
t40002002.xml 10.24388/ t40002002 A.W. Jasper, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 111 (2007) 3932-3950 Rate coefficient determination - HPCH3OH(+M)=OH+CH3(+M)  
t70002001.xml 10.24388/ t70002001 A.W. Jasper, S.J. Klippenstein, L.B. Harding, Proc. Combust. Inst. 32 (2009), 279-286 Rate coefficient determination - CH3+HO2=CH4+O2  
t80002001.xml 10.24388/ t80002001 H.Y. Li, M. Pu, Y.Q. Ji, Z.F. Xu, W.L. Feng, Chem. Phys. 307 (2004), 35-43 Rate coefficient determination - CH2O + OH = HCO + H2O  
t80002002.xml 10.24388/ t80002002 S.Xu, R.S. Zhu, M.C. Lin, Int. J. Chem. Kinet. 38 (2006), 322-326 Rate coefficient determination - CH2O+OH=HCO+H2O  
t80002003.xml 10.24388/ t80002003 V. Vasudevan, D.F. Davidson, R.K. Hanson, Int. J. Chem. Kinet. 37 (2005), 98-109 Rate coefficient determination - CH2O+OH=HCO+H2O  
x10002013.xml 10.24388/ x10002013 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy and Fuels 24 (2010), 5834-5843 Ignition delay measurement CH3OH O2 Ar
x20002008.xml 10.24388/ x20002008 K. Saeed, C.R. Stone, Combust. Flame 139 (2004), 152-166 laminar burning velocity measurement CH3OH O2 N2
x30002022.xml 10.24388/ x30002022 V. Aranda, J.M. Christensen, M.U. Alzueta, P. Glarborg, S. Gersen, Y. Gao, P. Marshall, Int. J. Chem. Kinet. 45 (2013), 283-294 outlet concentration measurement CH3OH O2 N2
x40002002_x.xml 10.24388/ x40002002_x K. Kumar, C.-J. Sung, Int. J. Chem. Kinet. 43 (2011), 175-184 CH3OH O2 Ar
x50002202pyrCH2O.xml 10.24388/ x50002202pyrCH2O S. Wang, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 1930-1938 concentration time profile measurement CH2O Ar
x00002001.xml 10.24388/ x00002001 G. Dayma, K. H. Ali, P. Dagaut, Proc. Combust. Inst. 31 (2007), 411-418 jet stirred reactor measurement CH3OH O2 H2O N2
x00002010_x.xml 10.24388/ x00002010_x K.W. Aniolek, R.D. Wilk, Energy and Fuels 9 (1995), 395-405 jet stirred reactor measurement CH3OH O2 N2
x00002015.xml 10.24388/ x00002015 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002016.xml 10.24388/ x00002016 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002017.xml 10.24388/ x00002017 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002018.xml 10.24388/ x00002018 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002019.xml 10.24388/ x00002019 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002020.xml 10.24388/ x00002020 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002021.xml 10.24388/ x00002021 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x00002022.xml 10.24388/ x00002022 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 jet stirred reactor measurement CH3OH O2 N2
x10002001.xml 10.24388/ x10002001 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002002.xml 10.24388/ x10002002 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002003.xml 10.24388/ x10002003 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002004.xml 10.24388/ x10002004 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002005.xml 10.24388/ x10002005 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002006.xml 10.24388/ x10002006 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002007_x.xml 10.24388/ x10002007_x C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar
x10002008.xml 10.24388/ x10002008 C.T. Bowman, Combust. Flame 25 (1975), 343-354 CH3OH O2 Ar CO
x10002009.xml 10.24388/ x10002009 D.F. Cooke, M.G. Dodson, A. Williams, Combust. Flame 16 (1971), 233-236 CH3OH O2 Ar
x10002010.xml 10.24388/ x10002010 K. Fieweger, R. Blumenthal, G. Adomeit, Combust. Flame, 109 (1997), 599-619 CH3OH O2 N2
x10002011.xml 10.24388/ x10002011 K. Fieweger, R. Blumenthal, G. Adomeit, Combust. Flame, 109 (1997), 599-619 CH3OH O2 N2
x10002012.xml 10.24388/ x10002012 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy and Fuels 24 (2010), 5834-5843 Ignition delay measurement CH3OH O2 Ar
x10002014.xml 10.24388/ x10002014 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy and Fuels 24 (2010), 5834-5843 Ignition delay measurement CH3OH O2 Ar
x10002015.xml 10.24388/ x10002015 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy and Fuels 24 (2010), 5834-5843 Ignition delay measurement CH3OH O2 Ar
x10002016.xml 10.24388/ x10002016 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy and Fuels 24 (2010), 5834-5843 Ignition delay measurement CH3OH O2 Ar
x10002017.xml 10.24388/ x10002017 K.E. Noorani, B. Akih-Kumgeh, J.M. Bergthorson, Energy and Fuels 24 (2010), 5834-5843 Ignition delay measurement CH3OH O2 Ar
x10002018.xml 10.24388/ x10002018 U. Burke (2012), unpublished data from NUI Galway, Case No. 1 CH3OH O2 N2
x10002019.xml 10.24388/ x10002019 U. Burke (2012), unpublished data from NUI Galway, Case No. 2 CH3OH O2 N2
x10002020.xml 10.24388/ x10002020 U. Burke (2012), unpublished data from NUI Galway, Case No. 3 CH3OH O2 N2
x10002021.xml 10.24388/ x10002021 U. Burke (2012), unpublished data from NUI Galway, Case No. 4 CH3OH O2 N2
x10002022.xml 10.24388/ x10002022 U. Burke (2012), unpublished data from NUI Galway, Case No. 5 CH3OH O2 N2
x10002023.xml 10.24388/ x10002023 U. Burke (2012), unpublished data from NUI Galway, Case No. 6 CH3OH O2 N2
x10002024.xml 10.24388/ x10002024 U. Burke (2012), unpublished data from NUI Galway, Case No. 7 CH3OH O2 N2
x10002025.xml 10.24388/ x10002025 U. Burke (2012), unpublished data from NUI Galway, Case No. 8 CH3OH O2 N2
x10002026.xml 10.24388/ x10002026 U. Burke (2012), unpublished data from NUI Galway, Case No. 9 CH3OH O2 N2
x10002027.xml 10.24388/ x10002027 U. Burke (2012), unpublished data from NUI Galway, Case No. 10 CH3OH O2 N2
x10002028.xml 10.24388/ x10002028 U. Burke (2012), unpublished data from NUI Galway, Case No. 11 CH3OH O2 N2
x10002029.xml 10.24388/ x10002029 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002030.xml 10.24388/ x10002030 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002031.xml 10.24388/ x10002031 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002032.xml 10.24388/ x10002032 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002033.xml 10.24388/ x10002033 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002034.xml 10.24388/ x10002034 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002035.xml 10.24388/ x10002035 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002036.xml 10.24388/ x10002036 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002037.xml 10.24388/ x10002037 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002038.xml 10.24388/ x10002038 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002039.xml 10.24388/ x10002039 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002040.xml 10.24388/ x10002040 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002041.xml 10.24388/ x10002041 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002042.xml 10.24388/ x10002042 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002043.xml 10.24388/ x10002043 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002044.xml 10.24388/ x10002044 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002045.xml 10.24388/ x10002045 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002046.xml 10.24388/ x10002046 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002047.xml 10.24388/ x10002047 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002048.xml 10.24388/ x10002048 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002049.xml 10.24388/ x10002049 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002050.xml 10.24388/ x10002050 T. Tsuboi, K. Hashimoto, Combust. Flame 42 (1981), 61-76 CH3OH O2 Ar
x10002051.xml 10.24388/ x10002051 K. Natarajan, K.A Bhaskaran, Combust. Flame 43 (1981), 35-49 CH3OH O2 Ar
x10002052.xml 10.24388/ x10002052 K. Natarajan, K.A Bhaskaran, Combust. Flame 43 (1981), 35-49 CH3OH O2 Ar
x10002053.xml 10.24388/ x10002053 K. Natarajan, K.A Bhaskaran, Combust. Flame 43 (1981), 35-49 CH3OH O2 Ar
x10002054.xml 10.24388/ x10002054 K. Natarajan, K.A Bhaskaran, Combust. Flame 43 (1981), 35-49 CH3OH O2 Ar
x10002055.xml 10.24388/ x10002055 K. Natarajan, K.A Bhaskaran, Combust. Flame 43 (1981), 35-49 CH3OH O2 Ar
x10002056.xml 10.24388/ x10002056 K. Natarajan, K.A Bhaskaran, Combust. Flame 43 (1981), 35-49 CH3OH O2 Ar
x10002058.xml 10.24388/ x10002058 U. Burke (2013), unpublished data from NUI Galway CH3OH O2 N2
x10002066.xml 10.24388/ x10002066 J. Herzler, C. Naumann: Ignition Delay Time Measurements for the Validation of Reaction Mechanisms for Different Alcohols. Proc. Europ. Combust Meeting 2013. Paper P3-8 CH3OH O2 Ar
x10002067.xml 10.24388/ x10002067 J. Herzler, C. Naumann: Ignition Delay Time Measurements for the Validation of Reaction Mechanisms for Different Alcohols. Proc. Europ. Combust Meeting 2013. Paper P3-8 CH3OH O2 Ar
x10002068.xml 10.24388/ x10002068 J. Herzler, C. Naumann: Ignition Delay Time Measurements for the Validation of Reaction Mechanisms for Different Alcohols. Proc. Europ. Combust Meeting 2013. Paper P3-8 CH3OH O2 Ar
x10002069.xml 10.24388/ x10002069 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2
x10002070.xml 10.24388/ x10002070 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2
x10002071.xml 10.24388/ x10002071 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2
x10002072.xml 10.24388/ x10002072 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2
x10002073.xml 10.24388/ x10002073 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2
x10002074.xml 10.24388/ x10002074 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 Ar
x10002075.xml 10.24388/ x10002075 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 Ar
x10002076.xml 10.24388/ x10002076 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 Ar
x10002077.xml 10.24388/ x10002077 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 Ar
x10002078.xml 10.24388/ x10002078 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2
x10002101pyr.xml 10.24388/ x10002101 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x10002102pyr.xml 10.24388/ x10002102 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x10002103.xml 10.24388/ x10002103 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x10002104.xml 10.24388/ x10002104 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x10002105.xml 10.24388/ x10002105 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x10002106.xml 10.24388/ x10002106 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x10002107.xml 10.24388/ x10002107 B. Eiteneer, C.-L. Yu, M. Goldenberg, M. Frenklach, J. Phys. Chem. A 102 (1998), 5196-5205 CH2O O2 Ar
x20002001.xml 10.24388/ x20002001 F.N. Egolfopoulos, D.X. Du, C.K. Law, Combust. Sci. Technol. 83 (1992), 33-75 laminar burning velocity measurement CH3OH O2 N2
x20002002.xml 10.24388/ x20002002 F.N. Egolfopoulos, D.X. Du, C.K. Law, Combust. Sci. Technol. 83 (1992), 33-75 laminar burning velocity measurement CH3OH O2 N2
x20002003.xml 10.24388/ x20002003 F.N. Egolfopoulos, D.X. Du, C.K. Law, Combust. Sci. Technol. 83 (1992), 33-75 laminar burning velocity measurement CH3OH O2 N2
x20002004.xml 10.24388/ x20002004 F.N. Egolfopoulos, D.X. Du, C.K. Law, Combust. Sci. Technol. 83 (1992), 33-75 laminar burning velocity measurement CH3OH O2 N2
x20002005.xml 10.24388/ x20002005 K. Saeed, C.R. Stone, Combust. Flame 139 (2004), 152-166 laminar burning velocity measurement CH3OH O2 N2
x20002006.xml 10.24388/ x20002006 K. Saeed, C.R. Stone, Combust. Flame 139 (2004), 152-166 laminar burning velocity measurement CH3OH O2 N2
x20002007.xml 10.24388/ x20002007 K. Saeed, C.R. Stone, Combust. Flame 139 (2004), 152-166 laminar burning velocity measurement CH3OH O2 N2
x20002009.xml 10.24388/ x20002009 K. Saeed, C.R. Stone, Combust. Flame 139 (2004), 152-166 laminar burning velocity measurement CH3OH O2 N2
x20002010.xml 10.24388/ x20002010 K. Saeed, C.R. Stone, Combust. Flame 139 (2004), 152-166 laminar burning velocity measurement CH3OH O2 N2
x20002011.xml 10.24388/ x20002011 S.Y. Liao, D.M. Jiang, Z.H. Huang, W.D. Shen, C. Yuan, Cheng, Q., Energy Conversion and Management 48 (2007), 857-863 laminar burning velocity measurement CH3OH O2 N2
x20002015.xml 10.24388/ x20002015 S.Y. Liao, D.M. Jiang, Z.H. Huang, W.D. Shen, C. Yuan, Cheng, Q., Energy Conversion and Management 48 (2007), 857-863 laminar burning velocity measurement CH3OH O2 N2
x20002016.xml 10.24388/ x20002016 S.Y. Liao, D.M. Jiang, Z.H. Huang, W.D. Shen, C. Yuan, Cheng, Q., Energy Conversion and Management 48 (2007), 857-863 laminar burning velocity measurement CH3OH O2 N2
x20002017_x.xml 10.24388/ x20002017_x D. Bradley, G. Dixon-Lewis, S.E. Habik, L.K. Kwa, S. El-Sherif, Combust. Flame 85 (1991), 105-120 laminar burning velocity measurement CH3OH O2 N2
x20002018.xml 10.24388/ x20002018 D. Bradley, G. Dixon-Lewis, S.E. Habik, L.K. Kwa, S. El-Sherif, Combust. Flame 85 (1991), 105-120 laminar burning velocity measurement CH3OH O2 N2
x20002019.xml 10.24388/ x20002019 D. Bradley, G. Dixon-Lewis, S.E. Habik, L.K. Kwa, S. El-Sherif, Combust. Flame 85 (1991), 105-120 laminar burning velocity measurement CH3OH O2 N2
x20002025.xml 10.24388/ x20002025 M. Hirano, K. Oda, T. Hirano, K. Akita, Combust. Flame 40 (1981), 341-343 laminar burning velocity measurement CH3OH O2 N2
x20002026.xml 10.24388/ x20002026 M. Hirano, K. Oda, T. Hirano, K. Akita, Combust. Flame 40 (1981), 341-343 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002027.xml 10.24388/ x20002027 M. Hirano, K. Oda, T. Hirano, K. Akita, Combust. Flame 40 (1981), 341-343 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002028.xml 10.24388/ x20002028 M. Hirano, K. Oda, T. Hirano, K. Akita, Combust. Flame 40 (1981), 341-343 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002029.xml 10.24388/ x20002029 M. Hirano, K. Oda, T. Hirano, K. Akita, Combust. Flame 40 (1981), 341-343 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002030.xml 10.24388/ x20002030 P.S. Veloo, Y.L. Wang, F.N. Egolfopoulos, C.K. Westbrook, Combust. Flame 157 (2010), 1989-2004 laminar burning velocity measurement CH3OH O2 N2
x20002031.xml 10.24388/ x20002031 Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002032.xml 10.24388/ x20002032 Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002033.xml 10.24388/ x20002033 Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002034.xml 10.24388/ x20002034 Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002035.xml 10.24388/ x20002035 Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002036_x.xml 10.24388/ x20002036_x Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002037_x.xml 10.24388/ x20002037_x Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002038_x.xml 10.24388/ x20002038_x Z. Zhang, Z. Huang, X. Wang, J. Xiang, X. Wang, H. Miao, Combust. Flame 155 (2008), 358-368 laminar burning velocity measurement CH3OH O2 N2
x20002057.xml 10.24388/ x20002057 M. Metghalchi, J.C. Keck, Combust. Flame 48 (1982), 191-210 laminar burning velocity measurement CH3OH O2 N2
x20002055.xml 10.24388/ x20002055 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002059.xml 10.24388/ x20002059 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002060.xml 10.24388/ x20002060 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002061.xml 10.24388/ x20002061 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002062.xml 10.24388/ x20002062 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002063.xml 10.24388/ x20002063 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002064.xml 10.24388/ x20002064 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002065.xml 10.24388/ x20002065 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002066.xml 10.24388/ x20002066 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002067.xml 10.24388/ x20002067 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002068.xml 10.24388/ x20002068 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002069.xml 10.24388/ x20002069 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002070.xml 10.24388/ x20002070 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002071.xml 10.24388/ x20002071 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002072.xml 10.24388/ x20002072 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002073.xml 10.24388/ x20002073 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002074.xml 10.24388/ x20002074 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002075.xml 10.24388/ x20002075 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002076.xml 10.24388/ x20002076 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002077.xml 10.24388/ x20002077 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002078.xml 10.24388/ x20002078 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002079.xml 10.24388/ x20002079 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002080.xml 10.24388/ x20002080 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002081.xml 10.24388/ x20002081 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002082.xml 10.24388/ x20002082 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002083.xml 10.24388/ x20002083 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002084.xml 10.24388/ x20002084 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002085.xml 10.24388/ x20002085 J. Vancoillie, M. Christensen, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Energy Fuels 26 (2012), 1557-1564 laminar burning velocity measurement CH3OH O2 N2
x20002086.xml 10.24388/ x20002086 G.J. Gibbs, H.F. Calcote, J. Chem. Eng. Data 4 (1959), 226-237 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002087_x.xml 10.24388/ x20002087_x G.J. Gibbs, H.F. Calcote, J. Chem. Eng. Data 4 (1959), 226-237 laminar burning velocity measurement CH3OH O2 N2 H2O
x20002088.xml 10.24388/ x20002088 J. Beeckmann, L. Cai, H. Pitsch, Fuel 117 (2014), 340-350 laminar burning velocity measurement CH3OH O2 N2
x20002089.xml 10.24388/ x20002089 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40 laminar burning velocity measurement CH3OH O2 N2
x20002090.xml 10.24388/ x20002090 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40 laminar burning velocity measurement CH3OH O2 N2
x20002091.xml 10.24388/ x20002091 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40 laminar burning velocity measurement CH3OH O2 N2
x20002092.xml 10.24388/ x20002092 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40 laminar burning velocity measurement CH3OH O2 N2
x20002093.xml 10.24388/ x20002093 L. Sileghem, V.A. Alekseev, J. Vancoillie, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Fuel 115 (2014), 32-40 laminar burning velocity measurement CH3OH O2 N2
x20002100.xml 10.24388/ x20002100 J.D. Naucler, L. Sileghem, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Combust. Flame 162 (2015), 1719-1728 laminar burning velocity measurement CH3OH O2 CO2
x20002101.xml 10.24388/ x20002101 J.D. Naucler, L. Sileghem, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Combust. Flame 162 (2015), 1719-1728 laminar burning velocity measurement CH3OH O2 CO2
x20002102.xml 10.24388/ x20002102 J.D. Naucler, L. Sileghem, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Combust. Flame 162 (2015), 1719-1728 laminar burning velocity measurement CH3OH O2 CO2
x20002103.xml 10.24388/ x20002103 J.D. Naucler, L. Sileghem, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Combust. Flame 162 (2015), 1719-1728 laminar burning velocity measurement CH3OH O2 CO2
x20002104.xml 10.24388/ x20002104 J.D. Naucler, L. Sileghem, E.J.K. Nilsson, S. Verhelst, A.A. Konnov, Combust. Flame 162 (2015), 1719-1728 laminar burning velocity measurement CH3OH O2 CO2
x30002001.xml 10.24388/ x30002001 M.U. Alzueta, R. Bilbao, M. Finestra, Energy and Fuels 15 (2001), 724-729 outlet concentration measurement CH3OH O2 H2O N2
x30002002.xml 10.24388/ x30002002 M.U. Alzueta, R. Bilbao, M. Finestra, Energy and Fuels 15 (2001), 724-729 outlet concentration measurement CH3OH O2 H2O N2
x30002003.xml 10.24388/ x30002003 M.U. Alzueta, R. Bilbao, M. Finestra, Energy and Fuels 15 (2001), 724-729 outlet concentration measurement CH3OH O2 H2O N2
x30002007.xml 10.24388/ x30002007 D. Aronowitz, R.J. Santoro, F.L. Dryer, I. Glassman, Symposium (International) on Combustion 17 (1979), 633-644 concentration time profile measurement CH3OH O2 N2
x30002008.xml 10.24388/ x30002008 D. Aronowitz, R.J. Santoro, F.L. Dryer, I. Glassman, Symposium (International) on Combustion 17 (1979), 633-644 concentration time profile measurement CH3OH O2 N2
x30002009.xml 10.24388/ x30002009 C.L. Rasmussen, K.H. Wassard, K. Dam-Johansen, P. Glarborg, Int. J. Chem. Kinet. 40 (2008), 423-441 outlet concentration measurement CH3OH O2 H2O N2
x30002010.xml 10.24388/ x30002010 C.L. Rasmussen, K.H. Wassard, K. Dam-Johansen, P. Glarborg, Int. J. Chem. Kinet. 40 (2008), 423-441 outlet concentration measurement CH3OH O2 H2O N2
x30002011.xml 10.24388/ x30002011 C.L. Rasmussen, K.H. Wassard, K. Dam-Johansen, P. Glarborg, Int. J. Chem. Kinet. 40 (2008), 423-441 outlet concentration measurement CH3OH O2 H2O N2
x30002012.xml 10.24388/ x30002012 C.L. Rasmussen, K.H. Wassard, K. Dam-Johansen, P. Glarborg, Int. J. Chem. Kinet. 40 (2008), 423-441 outlet concentration measurement CH3OH O2 H2O N2
x30002013.xml 10.24388/ x30002013 C.L. Rasmussen, K.H. Wassard, K. Dam-Johansen, P. Glarborg, Int. J. Chem. Kinet. 40 (2008), 423-441 outlet concentration measurement CH3OH O2 H2O N2
x30002019.xml 10.24388/ x30002019 V. Aranda, J.M. Christensen, M.U. Alzueta, P. Glarborg, S. Gersen, Y. Gao, P. Marshall, Int. J. Chem. Kinet. 45 (2013), 283-294 outlet concentration measurement CH3OH O2 N2
x30002020.xml 10.24388/ x30002020 V. Aranda, J.M. Christensen, M.U. Alzueta, P. Glarborg, S. Gersen, Y. Gao, P. Marshall, Int. J. Chem. Kinet. 45 (2013), 283-294 outlet concentration measurement CH3OH O2 N2
x30002021.xml 10.24388/ x30002021 V. Aranda, J.M. Christensen, M.U. Alzueta, P. Glarborg, S. Gersen, Y. Gao, P. Marshall, Int. J. Chem. Kinet. 45 (2013), 283-294 outlet concentration measurement CH3OH O2 N2
x30002023.xml 10.24388/ x30002023 V. Aranda, J.M. Christensen, M.U. Alzueta, P. Glarborg, S. Gersen, Y. Gao, P. Marshall, Int. J. Chem. Kinet. 45 (2013), 283-294 outlet concentration measurement CH3OH O2 N2
x30002024.xml 10.24388/ x30002024 T.S. Norton, F.L. Dryer, Combustion Science and Technology 63 (1989), 107-129 concentration time profile measurement CH3OH O2 N2
x30002025.xml 10.24388/ x30002025 T.S. Norton, F.L. Dryer, Combustion Science and Technology 63 (1989), 107-129 concentration time profile measurement CH3OH O2 N2
x30002026.xml 10.24388/ x30002026 T.S. Norton, F.L. Dryer, Combustion Science and Technology 63 (1989), 107-129 concentration time profile measurement CH3OH O2 N2
x30002027_x.xml 10.24388/ x30002027_x W.-C. Ing, C.Y. Sheng, J.W. Bozzelli, Fuel Processing Technology 83 (2003), 111-145 concentration time profile measurement CH3OH O2 Ar
x30002028_x.xml 10.24388/ x30002028_x W.-C. Ing, C.Y. Sheng, J.W. Bozzelli, Fuel Processing Technology 83 (2003), 111-145 concentration time profile measurement CH3OH O2 Ar
x30002029CH4_x.xml 10.24388/ x30002029CH4_x W.-C. Ing, C.Y. Sheng, J.W. Bozzelli, Fuel Processing Technology 83 (2003), 111-145 concentration time profile measurement CH3OH CH4 O2 Ar
x30002030CH4_x.xml 10.24388/ x30002030CH4_x W.-C. Ing, C.Y. Sheng, J.W. Bozzelli, Fuel Processing Technology 83 (2003), 111-145 concentration time profile measurement CH3OH CH4 O2 Ar
x30002031.xml 10.24388/ x30002031 T.J. Held, F.L. Dryer, Int. J. Chem. Kinet. 30 (1998), 805-830, Figure 12 concentration time profile measurement CH3OH O2 N2
x30002032.xml 10.24388/ x30002032 T.J. Held, F.L. Dryer, Int. J. Chem. Kinet. 30 (1998), 805-830, Figure 13 concentration time profile measurement CH3OH O2 N2
x30002033.xml 10.24388/ x30002033 T.J. Held, The Oxidation of Methanol, Isobutene and Methyl Tertiary-Butyl Ether, Ph.D. Thesis, Princeton University (1993) concentration time profile measurement CH3OH O2 N2
x30002034.xml 10.24388/ x30002034 T.J. Held, F.L. Dryer, Proc. Combust. Inst. 25 (1994) 901-908 concentration time profile measurement CH3OH O2 N2
x30002035.xml 10.24388/ x30002035 T.J. Held, F.L. Dryer, Int. J. Chem. Kinet. 30 (1998), 805-830 concentration time profile measurement CH3OH O2 N2
x30002036.xml 10.24388/ x30002036 T.J. Held, F.L. Dryer, Proc. Combust. Inst. 25 (1994) 901-908 concentration time profile measurement CH3OH O2 N2
x30002037.xml 10.24388/ x30002037 T.J. Held, F.L. Dryer, Int. J. Chem. Kinet. 30 (1998), 805-830 concentration time profile measurement CH3OH O2 N2
x30002038.xml 10.24388/ x30002038 T.J. Held, F.L. Dryer, Int. J. Chem. Kinet. 30 (1998), 805-830 concentration time profile measurement CH3OH O2 N2
x30002039_x.xml 10.24388/ x30002039_x T.J. Held, The Oxidation of Methanol, Isobutene and Methyl Tertiary-Butyl Ether, Ph.D. Thesis, Princeton University (1993) concentration time profile measurement CH3OH O2 N2
x30002040.xml 10.24388/ x30002040 T.J. Held, The Oxidation of Methanol, Isobutene and Methyl Tertiary-Butyl Ether, Ph.D. Thesis, Princeton University (1993) concentration time profile measurement CH3OH O2 N2
x30002041.xml 10.24388/ x30002041 T.J. Held, The Oxidation of Methanol, Isobutene and Methyl Tertiary-Butyl Ether, Ph.D. Thesis, Princeton University (1993) concentration time profile measurement CH3OH O2 N2
x30002042.xml 10.24388/ x30002042 T.J. Held, The Oxidation of Methanol, Isobutene and Methyl Tertiary-Butyl Ether, Ph.D. Thesis, Princeton University (1993) concentration time profile measurement CH3OH O2 N2
x30002043.xml 10.24388/ x30002043 T.J. Held, The Oxidation of Methanol, Isobutene and Methyl Tertiary-Butyl Ether, Ph.D. Thesis, Princeton University (1993) concentration time profile measurement CH3OH O2 N2
x30002044.xml 10.24388/ x30002044 Presumably: D. Aronowitz, The high temperature oxidation and pyrolysis of methanol. PhD Disseration, Princeton University, 1978. Digitized from: C.K. Westbrook, F.L. Dryer, Combust. Sci. Technol. 20 (1979), 125-140 concentration time profile measurement CH3OH O2 N2
x30002045_x.xml 10.24388/ x30002045_x Presumably: D. Aronowitz, The high temperature oxidation and pyrolysis of methanol. PhD Disseration, Princeton University, 1978. Digitized from: C.K. Westbrook, F.L. Dryer, Combust. Sci. Technol. 20 (1979), 125-140 concentration time profile measurement CH3OH O2 N2
x30002201CH2O.xml 10.24388/ x30002201CH2O S. Hochgreb, R.A. Yetter, F.L. Dryer, Proc. Combust. Inst. 23, 1990, 171-177, Fig. 1 concentration time profile measurement CH2O O2 N2
x30002202CH2O.xml 10.24388/ x30002202CH2O S. Hochgreb, R.A. Yetter, F.L. Dryer, Proc. Combust. Inst. 23, 1990, 171-177, Fig. 2 concentration time profile measurement CH2O O2 N2
x30002203CH2O.xml 10.24388/ x30002203CH2O S. Hochgreb, F.L. Dryer, Combust. Flame 91, 1992, 285-287, Fig. 1b concentration time profile measurement CH2O O2 N2
x30002204CH2O.xml 10.24388/ x30002204CH2O S. Hochgreb, F.L. Dryer, Combust. Flame 91, 1992, 285-287, Fig. 1a concentration time profile measurement CH2O O2 N2
x30002205CH2O.xml 10.24388/ x30002205CH2O S. Hochgreb, R.A. Yetter, F.L. Dryer, Proc. Combust. Inst. 23, 1990, 171-177, Figs. 3 and 4, full square concentration time profile measurement CH2O O2 N2
x30002206CH2O.xml 10.24388/ x30002206CH2O S. Hochgreb, R.A. Yetter, F.L. Dryer, Proc. Combust. Inst. 23, 1990, 171-177, Figs. 3 and 4, open square concentration time profile measurement CH2O O2 N2
x30002207CH2O.xml 10.24388/ x30002207CH2O S. Hochgreb, F.L. Dryer, Combust. Flame 91, 1992, 285-287, Fig. 1c concentration time profile measurement CH2O O2 N2
x30002208CH2O.xml 10.24388/ x30002208CH2O J. Li, Z. Zhao, A. Kazakhov, M. Chaos, F.L. Dryer, J.J. Scire, Jr., Int. J. Chem. Kinet. 109 (2007), 109-136, Fig. 19 bottom concentration time profile measurement CH2O O2 N2
x30002209CH2O.xml 10.24388/ x30002209CH2O S. Hochgreb, F.L. Dryer, Combust. Flame 91, 1992, 285-287, Fig. 3b concentration time profile measurement CH2O O2 N2
x30002210CH2O.xml 10.24388/ x30002210CH2O J. Li, Z. Zhao, A. Kazakhov, M. Chaos, F.L. Dryer, J.J. Scire, Jr., Int. J. Chem. Kinet. 109 (2007), 109-136 concentration time profile measurement CH2O O2 H2O N2
x30002211CH2O.xml 10.24388/ x30002211CH2O J. Li, Z. Zhao, A. Kazakhov, M. Chaos, F.L. Dryer, J.J. Scire, Jr., Int. J. Chem. Kinet. 109 (2007), 109-136 concentration time profile measurement CH2O O2 H2O N2
x30002212CH2O.xml 10.24388/ x30002212CH2O J. Li, Z. Zhao, A. Kazakhov, M. Chaos, F.L. Dryer, J.J. Scire, Jr., Int. J. Chem. Kinet. 109 (2007), 109-136 concentration time profile measurement CH2O O2 H2O N2
x30002213CH2O.xml 10.24388/ x30002213CH2O J. Li, Z. Zhao, A. Kazakhov, M. Chaos, F.L. Dryer, J.J. Scire, Jr., Int. J. Chem. Kinet. 109 (2007), 109-136 concentration time profile measurement CH2O O2 H2O N2
x30002214CH2O.xml 10.24388/ x30002214CH2O P. Glarborg, M.U. Alzueta, K. Kjaergaard, K. Dam-Johansen, Combust. Flame 132 (2003), 629-638 outlet concentration measurement CH2O O2 H2O N2
x30002215CH2O.xml 10.24388/ x30002215CH2O P. Glarborg, M.U. Alzueta, K. Kjaergaard, K. Dam-Johansen, Combust. Flame 132 (2003), 629-638 outlet concentration measurement CH2O O2 H2O N2
x30002216CH2O.xml 10.24388/ x30002216CH2O P. Glarborg, M.U. Alzueta, K. Kjaergaard, K. Dam-Johansen, Combust. Flame 132 (2003), 629-638 outlet concentration measurement CH2O O2 H2O N2
x40002001_x.xml 10.24388/ x40002001_x K. Kumar, C.-J. Sung, Int. J. Chem. Kinet. 43 (2011), 175-184 CH3OH O2 Ar
x40002003.xml 10.24388/ x40002003 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x40002004.xml 10.24388/ x40002004 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x40002005.xml 10.24388/ x40002005 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x40002006.xml 10.24388/ x40002006 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x40002007.xml 10.24388/ x40002007 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x40002008.xml 10.24388/ x40002008 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x40002009.xml 10.24388/ x40002009 U. Burke, W.K. Metcalfe, S.M. Burke, K.A. Heufer, P. Dagaut, H.J. Curran, Combust. Flame 165 (2016), 125-136 ignition delay measurement CH3OH O2 N2 Ar
x50002001.xml 10.24388/ x50002001pyr P.H. Cribb, J.E. Dove, S. Yamazaki, Combust. Flame 88 (1992), 186-200 CH3OH O2 Ar Ne
x50002002.xml 10.24388/ x50002002pyr P.H. Cribb, J.E. Dove, S. Yamazaki, Combust. Flame 88 (1992), 186-200 CH3OH O2 Ar Ne
x50002003pyr.xml 10.24388/ x50002003pyr P.H. Cribb, J.E. Dove, S. Yamazaki, Combust. Flame 88 (1992), 169-185 CH3OH H2 Ar Ne
x50002004pyr.xml 10.24388/ x50002004pyr P.H. Cribb, J.E. Dove, S. Yamazaki, Combust. Flame 88 (1992), 169-185 CH3OH Ar Ne
x50002005pyr.xml 10.24388/ x50002005pyr P.H. Cribb, J.E. Dove, S. Yamazaki, Proc. Combust. Inst. 20 (1984), 779-787 CH3OH H2 Ar Ne
x50002006pyr.xml 10.24388/ x50002006pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002007pyr.xml 10.24388/ x50002007pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002008pyr.xml 10.24388/ x50002008pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002009pyr.xml 10.24388/ x50002009pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002010pyr.xml 10.24388/ x50002010pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002011pyr.xml 10.24388/ x50002011pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002012pyr.xml 10.24388/ x50002012pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002013pyr.xml 10.24388/ x50002013pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 CH3OH Ar
x50002014pyr.xml 10.24388/ x50002014pyr W. Ren, E. Dames, D. Hyland, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 2669-2679 concentration time profile measurement CH3OH Ar
x50002201pyrCH2O.xml 10.24388/ x50002201pyrCH2O S. Wang, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 1930-1938 concentration time profile measurement CH2O Ar
x50002201pyrCH2O_full.xml 10.24388/ x50002201pyrCH2O S. Wang, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 1930-1938 concentration time profile measurement CH2O Ar
x50002202pyrCH2O_full.xml 10.24388/ x50002202pyrCH2O S. Wang, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 1930-1938 concentration time profile measurement CH2O Ar
x50002203pyrCH2O.xml 10.24388/ x50002203pyrCH2O S. Wang, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 1930-1938 concentration time profile measurement CH2O Ar
x50002203pyrCH2O_full.xml 10.24388/ x50002203pyrCH2O S. Wang, D.F. Davidson, R.K. Hanson, Combust. Flame 160 (2013), 1930-1938 concentration time profile measurement CH2O Ar
x50002204pyrCH2O.xml 10.24388/ x50002204pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002205pyrCH2O.xml 10.24388/ x50002205pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002206pyrCH2O.xml 10.24388/ x50002206pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002207pyrCH2O.xml 10.24388/ x50002207pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002208pyrCH2O.xml 10.24388/ x50002208pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002209pyrCH2O.xml 10.24388/ x50002209pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002210pyrCH2O.xml 10.24388/ x50002210pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002211pyrCH2O.xml 10.24388/ x50002211pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002212pyrCH2O.xml 10.24388/ x50002212pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002213pyrCH2O.xml 10.24388/ x50002213pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002214pyrCH2O.xml 10.24388/ x50002214pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002215pyrCH2O.xml 10.24388/ x50002215pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002216pyrCH2O.xml 10.24388/ x50002216pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002217pyrCH2O.xml 10.24388/ x50002217pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002218pyrCH2O.xml 10.24388/ x50002218pyrCH2O Y. Hidaka, T. Taniguchi, T. Kamesawa, H. Masaoka, K. Inami, H. Kawano, Int. J. Chem. Kinet. 25 (1993), 305-322 composition time profile measurement CH2O Ar
x50002219CH2O.xml 10.24388/ x50002219CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x50002220CH2O.xml 10.24388/ x50002220CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x50002221CH2O.xml 10.24388/ x50002221CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x50002222CH2O.xml 10.24388/ x50002222CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x50002223CH2O.xml 10.24388/ x50002223CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376, composition time profile measurement CH2O O2 Ar
x50002224CH2O.xml 10.24388/ x50002224CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376, composition time profile measurement CH2O O2 Ar
x50002225CH2O.xml 10.24388/ x50002225CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x50002226CH2O.xml 10.24388/ x50002226CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x50002227CH2O.xml 10.24388/ x50002227CH2O Y. Hidaka, T. Taniguchi, H. Tanaka, T. Kamesawa, K. Inami, H. Kawano, Combust. Flame 92 (1993), 365-376 composition time profile measurement CH2O O2 Ar
x20002094.xml 10.24388/ x20002094 S. Voss, F. Rau, V.A. Alekseev, A.A. Konnov, R. Haas-Wittmuess, R.T.E. Hermanns, E. Volkov, L.P.H. de Goey, Proc. Europ. Combust. Meeting 2015, P3-46 laminar burning velocity measurement CH3OH O2 N2
x20002095.xml 10.24388/ x20002095 S. Voss, F. Rau, V.A. Alekseev, A.A. Konnov, R. Haas-Wittmuess, R.T.E. Hermanns, E. Volkov, L.P.H. de Goey, Proc. Europ. Combust. Meeting 2015, P3-46 laminar burning velocity measurement CH3OH O2 N2
x20002012.xml 10.24388/ x20002012 S.Y. Liao, D.M. Jiang, Z.H. Huang, W.D. Shen, C. Yuan, Cheng, Q., Energy Conversion and Management 48 (2007), 857-863 laminar burning velocity measurement CH3OH O2 N2
x20002013.xml 10.24388/ x20002013 S.Y. Liao, D.M. Jiang, Z.H. Huang, W.D. Shen, C. Yuan, Cheng, Q., Energy Conversion and Management 48 (2007), 857-863 laminar burning velocity measurement CH3OH O2 N2
x20002014_x.xml 10.24388/ x20002014_x S.Y. Liao, D.M. Jiang, Z.H. Huang, W.D. Shen, C. Yuan, Cheng, Q., Energy Conversion and Management 48 (2007), 857-863 laminar burning velocity measurement CH3OH O2 N2
x20002039.xml 10.24388/ x20002039 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002040.xml 10.24388/ x20002040 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002041.xml 10.24388/ x20002041 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002042.xml 10.24388/ x20002042 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002043.xml 10.24388/ x20002043 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002044.xml 10.24388/ x20002044 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002045.xml 10.24388/ x20002045 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002046.xml 10.24388/ x20002046 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002047.xml 10.24388/ x20002047 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002048.xml 10.24388/ x20002048 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002049.xml 10.24388/ x20002049 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002050.xml 10.24388/ x20002050 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002051.xml 10.24388/ x20002051 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002052.xml 10.24388/ x20002052 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002053.xml 10.24388/ x20002053 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002054.xml 10.24388/ x20002054 O.L. Guelder, Proc. Combust. Inst. 19 (1982), 275-281 laminar burning velocity measurement CH3OH O2 N2
x20002058_x.xml 10.24388/ x20002058_x O.L. Guelder, Combust. Sci. Technol. 33 (1983), 179-192 laminar burning velocity measurement CH3OH O2 N2
INFO BOX
 
INFO BOX
XML file g00000001psr.xml
File DOI 10.24388/g00000001psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 1. H2 open diamond, H2O open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 800
T max /K 1050
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000001_x.xml
File DOI 10.24388/g00000001_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Chaumeix, N., Pichon, S., Lafosse, F., Paillard, C.-E., International Journal of Hydrogen Energy, 2007, (32) 2216-2226, Fig. 12., left, open diamond
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1181.06
T max /K 1343.27
p min /atm 2.05
p max /atm 2.05
INFO BOX
XML file g00000002psr.xml
File DOI 10.24388/g00000002psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 2. H2 open diamond, H2O open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 825
T max /K 1000
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000002_x.xml
File DOI 10.24388/g00000002_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Chaumeix, N., Pichon, S., Lafosse, F., Paillard, C.-E., International Journal of Hydrogen Energy 2007, (32) 2216-2226, Fig. 12., center, open diamond
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1184.03
T max /K 1359.29
p min /atm 2.1
p max /atm 2.1
INFO BOX
XML file g00000003psr.xml
File DOI 10.24388/g00000003psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 3. H2 open diamond, H2O open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1025
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000003_x.xml
File DOI 10.24388/g00000003_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Chaumeix, N., Pichon, S., Lafosse, F., Paillard, C.-E., International Journal of Hydrogen Energy, 2007, (32) 2216-2226, Fig. 12., right, open diamond
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1164.48
T max /K 1519.18
p min /atm 2.18
p max /atm 2.18
INFO BOX
XML file g00000004psr_x.xml
File DOI 10.24388/g00000004psr_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 4. H2 open diamond, H2O open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 820
T max /K 1150
p min /atm 10
p max /atm 10
INFO BOX
XML file g00000005psr.xml
File DOI 10.24388/g00000005psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 5. H2 open diamond, H2O open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1150
p min /atm 10
p max /atm 10
INFO BOX
XML file g00000006psr.xml
File DOI 10.24388/g00000006psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 6. H2 open diamond, O2 open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 886
T max /K 1097
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000007.xml
File DOI 10.24388/g00000007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Pang, G.A., Davison, D.F., Hanson, R.K., Proceedings of the Combustion Institute, 2009, (32), 181-188, Fig. 3., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 924
T max /K 1118
p min /atm 3.374
p max /atm 3.711
INFO BOX
XML file g00000007psr.xml
File DOI 10.24388/g00000007psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 7. H2 open diamond, O2 open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 888
T max /K 1026
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000008.xml
File DOI 10.24388/g00000008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Pang, G.A., Davison, D.F., Hanson, R.K., Proceedings of the Combustion Institute, 2009, (32), 181-188, Fig. 5., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 906
T max /K 1049
p min /atm 3
p max /atm 3.5
INFO BOX
XML file g00000008psr.xml
File DOI 10.24388/g00000008psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 8. H2 open diamond, O2 open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1028
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000009.xml
File DOI 10.24388/g00000009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 12., full triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 923
T max /K 1027
p min /atm 1.02
p max /atm 1.1
INFO BOX
XML file g00000009psr.xml
File DOI 10.24388/g00000009psr
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Le Cong, T., Dagaut,P., Energy and Fuels, 2009, (23), (1), 725-734., Fig. 9. H2 open diamond, O2 open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1049
p min /atm 1
p max /atm 1
INFO BOX
XML file g00000010.xml
File DOI 10.24388/g00000010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 12., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 958
T max /K 1035
p min /atm 3.78
p max /atm 4.09
INFO BOX
XML file g00000011_x.xml
File DOI 10.24388/g00000011_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 12., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1018
T max /K 1121
p min /atm 15.13
p max /atm 16.37
INFO BOX
XML file g00000012.xml
File DOI 10.24388/g00000012
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 13., full triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 918
T max /K 1718
p min /atm 0.87
p max /atm 1.13
INFO BOX
XML file g00000013.xml
File DOI 10.24388/g00000013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 13., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 962
T max /K 1160
p min /atm 3.82
p max /atm 4.12
INFO BOX
XML file g00000014_x.xml
File DOI 10.24388/g00000014_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Herzler, J., Naumann, C., Proceedings of the Combustion Institute, 2009, (32), 213-220, Fig. 13., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1015
T max /K 1238
p min /atm 14.64
p max /atm 19.27
INFO BOX
XML file gal_fl_1.xml
File DOI 10.24388/gal_fl_1
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Koroll, G.W., Kumar, R.K., Bowles, E.M., Combustion and Flame, 1993, (94), (3), 330-340., Fig. 4., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type laminar burning velocity measurement
Apparatus flame, premixed, laminar
Reaction  
T min /K 298
T max /K 298
p min /bar 1
p max /bar 1
INFO BOX
XML file gal_fl_3.xml
File DOI 10.24388/gal_fl_3
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Bradley, Lawes, D.M., Liu, K., Verhelst, S., Woolley, R., Combustion and Flame 2007, (149), (1-2), 162-172., Fig. 10., open circle, 0.1 MPa
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type laminar burning velocity measurement
Apparatus flame, premixed, laminar
Reaction  
T min /K 365
T max /K 365
p min /bar 1
p max /bar 1
INFO BOX
XML file gal_fl_4.xml
File DOI 10.24388/gal_fl_4
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Bradley, Lawes, D.M., Liu, K., Verhelst, S., Woolley, R., Combustion and Flame 2007, (149), (1-2), 162-172., Fig. 10., open circle, 0.5 MPa
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type laminar burning velocity measurement
Apparatus flame, premixed, laminar
Reaction  
T min /K 365
T max /K 365
p min /bar 5
p max /bar 5
INFO BOX
XML file gal_fl_5.xml
File DOI 10.24388/gal_fl_5
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Bradley, Lawes, D.M., Liu, K., Verhelst, S., Woolley, R., Combustion and Flame 2007, (149), (1-2), 162-172., Fig. 10., open circle, 1 MPa
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type laminar burning velocity measurement
Apparatus flame, premixed, laminar
Reaction  
T min /K 365
T max /K 365
p min /bar 10
p max /bar 10
INFO BOX
XML file k00000001.xml
File DOI 10.24388/k00000001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Masten, D.A., Hanson, R.K., Bowman, C.T., Journal of Physical Chemistry, 1990, (94), 7119-7128., Table II.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 1449
T max /K 3370
p min /   
p max /   
INFO BOX
XML file k00000002.xml
File DOI 10.24388/k00000002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Masten, D.A., Hanson, R.K., Bowman, C.T., Journal of Physical Chemistry, 1990, (94), 7119-7128., Table III.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 1452
T max /K 2152
p min /   
p max /   
INFO BOX
XML file k00000003.xml
File DOI 10.24388/k00000003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Du, H., Hessler, J.P., Journal of Chemical Physics, 1992, (96), 1077-1092., Table II.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 2050
T max /K 2946
p min /   
p max /   
INFO BOX
XML file k00000004.xml
File DOI 10.24388/k00000004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Yang, H, Gardiner, W.C., Shin, K.S., Fujii, N., Chemical Physics Letters, 1994, (231), (4-6), 449-453., Table 2.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 1849
T max /K 3549
p min /   
p max /   
INFO BOX
XML file k00000005.xml
File DOI 10.24388/k00000005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Ryu, S.O., Hwang, S.M., Rabinowitz, M.J., Journal of Physical Chemistry, 1995, (99), 13984-13991., Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 1052
T max /K 2501
p min /   
p max /   
INFO BOX
XML file k00000006.xml
File DOI 10.24388/k00000006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Mueller, M.A., Yetter, R.A., Dryer,F.L., Proceedings of the Combustion Institute, 1998, (27), 177-184., Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP H + O2 + M = HO2 + M
T min /K 830
T max /K 862
p min /   
p max /   
INFO BOX
XML file k00000007.xml
File DOI 10.24388/k00000007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Mueller, M.A., Yetter, R.A., Dryer,F.L., Proceedings of the Combustion Institute, 1998, (27), 177-184., Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP H + O2 + M = HO2 + M
T min /K 819
T max /K 826
p min /   
p max /   
INFO BOX
XML file k00000008.xml
File DOI 10.24388/k00000008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Pirraglia, A.N., Michael, J.V., Sutherland, J.W., Klemm, R.B., Journal of Physical Chemistry, 1989, (93), 282-291., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 962
T max /K 1705
p min /   
p max /   
INFO BOX
XML file k00000009.xml
File DOI 10.24388/k00000009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Shin, K.S., Michael,J.V., Journal of Chemical Physics, 1991, (95), 262-273., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 1103
T max /K 2059
p min /   
p max /   
INFO BOX
XML file k00000010.xml
File DOI 10.24388/k00000010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Ashman, P.J., Haynes, B.S., Proceedings of the Combustion Institute, 1998, (27), 185-191., Fig. 5., full inverse triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP H + O2 + M = HO2 + M
T min /K 725.1684
T max /K 899.3291
p min /   
p max /   
INFO BOX
XML file k00000012.xml
File DOI 10.24388/k00000012
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hwang, S.M., Ryu, S.O., De Witt, K.J., Rabinowitz, M.J., Chemical Physics Letters, 2005, (408), (1-3), 107-111., Fig. 3., open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + O2 = OH + O
T min /K 948.3032
T max /K 3097.394
p min /   
p max /   
INFO BOX
XML file k00000013.xml
File DOI 10.24388/k00000013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Getzinger, R.W., Schott,G.L., Journal of Chemical Physics, 1965, (43), (9), 3237-3247., Table III.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPH+O2+M=HO2+M
T min /K 1164
T max /K 1849
p min /   
p max /   
INFO BOX
XML file k00000014.xml
File DOI 10.24388/k00000014
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Getzinger, R.W., Blair, L.S., Combustion and Flame, 1969, (13), (3), 271-284., Table 2.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPH+O2+M=HO2+M
T min /K 1306
T max /K 1612
p min /   
p max /   
INFO BOX
XML file k00000015.xml
File DOI 10.24388/k00000015
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Blair,L.S., Getzinger, R.W., Combustion and Flame, 1970, (14), (1), 5-12., Table 2.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPH+O2+M=HO2+M
T min /K 1435
T max /K 1650
p min /   
p max /   
INFO BOX
XML file k00000016.xml
File DOI 10.24388/k00000016
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Michael, J.V., Su, M.-C., Sutherland, J.W., Carroll, J.J., A. F. Wagner, Journal of Physical Chemistry A, 2002, (106), 5297-5313., Fig. 5., H + O2 + N2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPH+O2+M=HO2+M
T min /K 298.8615
T max /K 707.5873
p min /   
p max /   
INFO BOX
XML file k00000017.xml
File DOI 10.24388/k00000017
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Michael, J.V., Su, M.-C., Sutherland, J.W., Carroll, J.J., A. F. Wagner, Journal of Physical Chemistry A, 2002, (106), 5297-5313., Fig. 5., H + O2 + Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPH+O2+M=HO2+M
T min /K 294.5981
T max /K 706.9033
p min /   
p max /   
INFO BOX
XML file k00000018.xml
File DOI 10.24388/k00000018
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Sutherland, J.W., Michael, J.V., Pirraglia, A.N., Nesbitt, F.L., Klemm, R.B., Proceedings of the Combustion Institute 1986, (21), 929-941., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 504
T max /K 2495
p min /   
p max /   
INFO BOX
XML file k00000019.xml
File DOI 10.24388/k00000019
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Ryu, S.O., Hwang, S.M., Rabinowitz, M.J., Chemical Physics Letters, 1995, (242), (3), 279_284., Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 1424
T max /K 2427
p min /   
p max /   
INFO BOX
XML file k00000020.xml
File DOI 10.24388/k00000020
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Davidson, D.F., Hanson, R.K., Combustion and Flame, 1990, (82), (3_4), 445_447., Fig. 2., full circle + open diamond
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 2118.083
T max /K 2752.993
p min /   
p max /   
INFO BOX
XML file k00000021.xml
File DOI 10.24388/k00000021
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Presser, N., Gordon, R.J., Journal of Chemical Physics, 1985, (82), (3), 1291_297., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 296.6
T max /K 471.1
p min /   
p max /   
INFO BOX
XML file k00000022.xml
File DOI 10.24388/k00000022
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Light, G.C., Matsumoto, J.H., International Journal of Chemical Kinetics, 1980, (12), (7), 451_468.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 316.0456
T max /K 392.4185
p min /   
p max /   
INFO BOX
XML file k00000023.xml
File DOI 10.24388/k00000023
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Michael, J.V., Sutherland, J.W., Journal of Physical Chemistry, 1988, (92), 3853-3857., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + H2O = OH + H2
T min /K 1246
T max /K 2297
p min /   
p max /   
INFO BOX
XML file k00000024.xml
File DOI 10.24388/k00000024
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Oldenborg, R.C., Loge, G.W., Harradine, D.M., Winn, K.R., Journal of Chemical Physics, 1992, (96), 8426-8430., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction OH+H2=H+H2O
T min /K 809
T max /K 1548
p min /   
p max /   
INFO BOX
XML file k00000025.xml
File DOI 10.24388/k00000025
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Davidson, D.F., Chang, A.Y., Hanson,R.K., Symposium (International) on Combustion, 1989, (22), (1), 1877-1885., Fig. 7., full diamond + full triangle + full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + H2O = OH + H2
T min /K 1648.196
T max /K 2487.005
p min /   
p max /   
INFO BOX
XML file k00000026.xml
File DOI 10.24388/k00000026
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Frank, Ber. Bunsenges. Phys. Chem. 1985, p. 186, Fig. 10, Curve II
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction OH+H2=H+H2O
T min /K 1691.744
T max /K 2584.033
p min /   
p max /   
INFO BOX
XML file k00000027.xml
File DOI 10.24388/k00000027
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Ravishankara, A.R., Nicovich, J.M., Thompson, R.L., Tully, F.P., Journal of Physical Chemistry, 1981, (85), 2498-2503., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction OH+H2=H+H2O
T min /K 250
T max /K 1050
p min /   
p max /   
INFO BOX
XML file k00000028.xml
File DOI 10.24388/k00000028
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Tully, F.P., Ravishankara, A.R., Journal of Physical Chemistry, 1980, (84), 3126-3130., Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction OH+H2=H+H2O
T min /K 298
T max /K 992
p min /   
p max /   
INFO BOX
XML file k00000032.xml
File DOI 10.24388/k00000032
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hong, Z., Farooq, A., Barbour, E.A., Davidson, D.F., Hanson, R.K., Journal of Physical Chemistry A, 2009, (113), 12919-12925., Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition Ar H2O H2O2
Experimental type  
Apparatus  
Reaction H2O2 + M = 2OH + M
T min /K 1009
T max /K 1216
p min /atm 0.85
p max /atm 3.352
INFO BOX
XML file k00000033.xml
File DOI 10.24388/k00000033
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hong, Z., Cook, R.D., Davidson, D.F., Hanson, R.K., Journal of Physical Chemistry A, 2010, (114), 5718-5727., Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition Ar H2O H2O2
Experimental type  
Apparatus  
Reaction H2O2 + M = 2OH + M
T min /K 1020
T max /K 1461
p min /atm 1.039
p max /atm 2.239
INFO BOX
XML file k00000034.xml
File DOI 10.24388/k00000034
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Michael, J.V., Sutherland, J.W., Harding, L.B., Wagner, A.F., Proceedings of the Combustion Institute, 2000, (28), 1471-1478., Table 2.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H2 + O2 = HO2 + H
T min /K 1662
T max /K 2097
p min /   
p max /   
INFO BOX
XML file k00000035.xml
File DOI 10.24388/k00000035
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Javoy, S., Naudet, V., Abid, S., Paillard, C.E., International Journal of Chemical Kinetics, (32), 686-695, 2000, Table III.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 2691
T max /K 3356
p min /   
p max /   
INFO BOX
XML file k00000036.xml
File DOI 10.24388/k00000036
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. Natarjan, K., Roth, P., Combustion and Flame, (70), 267-279, 1987, Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 1713
T max /K 3532
p min /   
p max /   
INFO BOX
XML file k00000037.xml
File DOI 10.24388/k00000037
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. Natarjan, K., Roth, P., Combustion and Flame, (70), 267-279, 1987, Table 2.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 2109
T max /K 2800
p min /   
p max /   
INFO BOX
XML file k00000038.xml
File DOI 10.24388/k00000038
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Sutherland, J.W., Michael, J.V., Pirraglia, A.N., Nesbitt, F.L., Klemm, R.B., Twenty-first Symposium (International) on Combustion/The Combustion Institute, 929-941, 1986, Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 880
T max /K 2495
p min /   
p max /   
INFO BOX
XML file k00000039.xml
File DOI 10.24388/k00000039
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Davidson, D.F., Hanson, R.K., Combustion and Flame, (82), 445-447, 1990, Table II.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O + H2 = OH + H
T min /K 504
T max /K 932
p min /   
p max /   
INFO BOX
XML file k00000041.xml
File DOI 10.24388/k00000041
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hippler, H., Neunaber, H., Troe, J., Journal of Chemical Physics, (103), 3510-3516, 1995, Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HO2 + OH = H2O + O2
T min /K 1118
T max /K 1566
p min /   
p max /   
INFO BOX
XML file k00000042.xml
File DOI 10.24388/k00000042
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hong, Z., Vasu, S.S., Davidson, D.F., Hanson, R.K., Journal of Physical Chemistry A, (114), 5520-5525, 2010, Fig. 6.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H2O + O2 = HO2 + OH
T min /K 1592
T max /K 2118
p min /   
p max /   
INFO BOX
XML file k00000045.xml
File DOI 10.24388/k00000045
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Kappel, Ch., Luther, K., Troe, J., Physical Chemistry Chemical Physics, (4), 4392-4398, 2002, Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition Ar H2O2
Experimental type  
Apparatus  
Reaction H2O2 (+ M) = 2OH (+ M)
T min /K 954
T max /K 1240
p min /atm 3.03
p max /atm 3.64
INFO BOX
XML file k00000046.xml
File DOI 10.24388/k00000046
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Kappel, Ch., Luther, K., Troe, J., Physical Chemistry Chemical Physics, (4), 4392-4398, 2002, Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition Ar H2O2
Experimental type  
Apparatus  
Reaction H2O2 (+ M) = 2OH (+ M)
T min /K 1017
T max /K 1289
p min /atm 0.73
p max /atm 0.78
INFO BOX
XML file k00000047.xml
File DOI 10.24388/k00000047
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Kappel, Ch., Luther, K., Troe, J., Physical Chemistry Chemical Physics, (4), 4392-4398, 2002, Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition Ar H2O2
Experimental type  
Apparatus  
Reaction H2O2 (+ M) = 2OH (+ M)
T min /K 972
T max /K 1231
p min /atm 14.55
p max /atm 15.64
INFO BOX
XML file k00000050.xml
File DOI 10.24388/k00000050
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hong,Z., Davidson, D.F., Barbour, E.A., Hanson, R.K., Proceedings of the Combustion Institute 2011, (33), 309-316, Fig. 5., full circle, data from the supplement
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H+O2=OH+O
T min /K 1091
T max /K 1527
p min /   
p max /   
INFO BOX
XML file k00000052.xml
File DOI 10.24388/k00000052
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hong, Z., Lam, K-Y., Sur, R., Wang, S., Davidson, D. F., Hanson, R. K., Proceedings of the Combustion Institute, 2012, Supplementary Material, Table S-1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HO2 + OH = H2O + O2
T min /K 1072
T max /K 1283
p min /atm 1.546
p max /atm 1.786
INFO BOX
XML file k00000053.xml
File DOI 10.24388/k00000053
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Hong, Z., Lam, K-Y., Sur, R., Wang, S., Davidson, D. F., Hanson, R. K., Proceedings of the Combustion Institute, 2012, Supplementary Material, Table S-1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2O2
Experimental type  
Apparatus  
Reaction 2HO2 = H2O2 + O2
T min /K 1072
T max /K 1283
p min /atm 1.546
p max /atm 1.786
INFO BOX
XML file k00000057.xml
File DOI 10.24388/k00000057
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Yang, Chemical Physics Letters, 1993, p. 72, Fig. 3
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction O+H2=OH+H
T min /K 1610.397
T max /K 2134.923
p min /   
p max /   
INFO BOX
XML file k00000060.xml
File DOI 10.24388/k00000060
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Lam, K-Y., Davidson, D.F., Hanson, R.K., Journal of Chemical Kinetics, 2012, Table 2, sorted by T
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction OH + H2 = H + H2O
T min /K 902
T max /K 1518
p min /atm 1.15
p max /atm 1.52
INFO BOX
XML file k00000061.xml
File DOI 10.24388/k00000061
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; J. Troe; J. Willner, Journal of Chemical Physics 1990, 93, 1755-1760, Fig. 4, full square: from H2O2 thermal decomposition experiments
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction 2HO2 = H2O2 + O2
T min /K 960.5
T max /K 1131.6
p min /   
p max /   
INFO BOX
XML file k00000062.xml
File DOI 10.24388/k00000062
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; J. Troe; J. Willner, Journal of Chemical Physics 1990, 93, 1755-1760, Fig. 4, open square: from experiments with (CH3O)2/O2 mixtures
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction 2HO2 = H2O2 + O2
T min /K 787.1
T max /K 1090
p min /   
p max /   
INFO BOX
XML file k00000063.xml
File DOI 10.24388/k00000063
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Kappel; K. Luther; J. Troe, Physical Chemistry Chemical Physics 2002, 4, 4392-4398, Table 1a
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction 2HO2 = H2O2 + O2
T min /K 954
T max /K 1240
p min /atm 3.03
p max /atm 3.64
INFO BOX
XML file k00000064.xml
File DOI 10.24388/k00000064
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Table 10, Data from Baldwin et al. in different publications; partly averaged
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H2O2+H =H2+HO2
T min /K 713
T max /K 773
p min /   
p max /   
INFO BOX
XML file k00000070.xml
File DOI 10.24388/k00000070
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. J. Halstead; D. R. Jenkins, Symposium (International) on Combustion 1969, 12, (1), 979-987, Table I
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + OH + M = H2O + M
T min /K 1800
T max /K 2000
p min /   
p max /   
INFO BOX
XML file k00000071.xml
File DOI 10.24388/k00000071
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. J. Halstead; D. R. Jenkins, Symposium (International) on Combustion 1969, 12, (1), 979-987, Table I
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + OH + M = H2O + M
T min /K 1800
T max /K 2000
p min /   
p max /   
INFO BOX
XML file k00000072.xml
File DOI 10.24388/k00000072
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. J. Halstead; D. R. Jenkins, Symposium (International) on Combustion 1969, 12, (1), 979-987, Table I
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction H + OH + M = H2O + M
T min /K 1800
T max /K 2000
p min /   
p max /   
INFO BOX
XML file k00000075.xml
File DOI 10.24388/k00000075
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Z. Hong; D. F. Davidson; K.-Y. Lam; R. K. Hanson, Combustion and Flame 2012, 159, (10), 3007-3013, Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2O2 CH4 Ar
Experimental type  
Apparatus  
Reaction H2O2(+M) = 2OH(+M)
T min /K 1054
T max /K 1249
p min /atm 3.256
p max /atm 3.772
INFO BOX
XML file k00000081.xml
File DOI 10.24388/k00000081
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A. Gay; N. H. Pratt, Proc. Int. Symp. Shock Tubes Waves 1971, 8, Fig. 9, open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP H+O2+M=HO2+M
T min /K 1767
T max /K 2155
p min /   
p max /   
INFO BOX
XML file k00000083.xml
File DOI 10.24388/k00000083
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. K. Srinivasan; M.-C. Su; J. W. Sutherland; J. V. Michael; B. Ruscic, The Journal of Physical Chemistry A 2006, 110, (21), 6602-6607, Table 2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HO2 + OH = H2O + O2
T min /K 1237
T max /K 1554
p min /   
p max /   
INFO BOX
XML file k10001001.xml
File DOI 10.24388/k10001001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography M. S. Wooldridge; R. K. Hanson; C. T. Bowman, Symposium (International) on Combustion 1994, 25, (1), 741-748, Table 2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1086
T max /K 2365
p min /atm 0.185
p max /atm 0.815
INFO BOX
XML file k10001002.xml
File DOI 10.24388/k10001002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A. A. Westenberg; N. deHaas, The Journal of Chemical Physics 1973, 58, (10), 4061-4065, Table I
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 298
T max /K 915
p min /atm 0.0263
p max /atm 0.0263
INFO BOX
XML file k10001003.xml
File DOI 10.24388/k10001003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A. R. Ravishankara; R. L. Thompson, Chemical Physics Letters 1983, 99, (5-6), 377-381, Table 1
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 251
T max /K 1040
p min /atm 0.13158
p max /atm 0.13158
INFO BOX
XML file k10001004.xml
File DOI 10.24388/k10001004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography T. A. Brabbs; F. E. Belles; R. S. Brokaw, Proceedings of The Combustion Institute 1970, 13, 129-136, Table V
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 CO2 Ar
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1297
T max /K 1899
p min /atm 0.897
p max /atm 1.537
INFO BOX
XML file k10001005.xml
File DOI 10.24388/k10001005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series A: 4.0% H2-0.5% O2-3.0% CO2-Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO2 O2 Ar
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1709
T max /K 2324
p min /atm 1.61
p max /atm 2.44
INFO BOX
XML file k10001006.xml
File DOI 10.24388/k10001006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series B: 2.0% H2-0.5% O2-5.0% CO2-Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO2 O2 Ar
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1617
T max /K 2325
p min /atm 1.75
p max /atm 3.13
INFO BOX
XML file k10001007.xml
File DOI 10.24388/k10001007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series C: 2.0% H2-0.5% O2-7.0% CO2-Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO2 O2 Ar
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1817
T max /K 2469
p min /atm 1.55
p max /atm 1.68
INFO BOX
XML file k10001008.xml
File DOI 10.24388/k10001008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series D: 2.0% H2-1.0% O2-5.0% CO2-Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO2 O2 Ar
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1944
T max /K 2165
p min /atm 2.52
p max /atm 2.8
INFO BOX
XML file k10001009.xml
File DOI 10.24388/k10001009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Golden; G. P. Smith; A. B. McEwen; C. L. Yu; B. Eiteneer; M. Frenklach; G. L. Vaghjiani; A. R. Ravishankara; F. P. Tully, The Journal of Physical Chemistry A 1998, 102, (44), 8598-8606, Table 1, Series E: 2.0% H2-2.0% O2-7.0% CO2-Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO2 O2 Ar
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1427
T max /K 2253
p min /atm 1.64
p max /atm 2.29
INFO BOX
XML file k10001013.xml
File DOI 10.24388/k10001013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography W. C. Gardiner Jr; W. G. Mallard; M. McFarland; K. Morinaga; J. H. Owen; W. T. Rawlins; T. Takeyama; B. F. Walker, Symposium (International) on Combustion 1973, 14, (1), 61-75, Figure 7, cross
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1506
T max /K 2011
p min /   
p max /   
INFO BOX
XML file k10001014.xml
File DOI 10.24388/k10001014
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography M. S. Wooldridge; R. K. Hanson; C. T. Bowman, International Journal of Chemical Kinetics 1996, 28, (5), 361-372, Fig. 5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1085.431
T max /K 2369.157
p min /   
p max /   
INFO BOX
XML file k10001015.xml
File DOI 10.24388/k10001015
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Vandooren; J. Peeters; P. J. V. Tiggelen, Symposium (International) on Combustion 1975, 15, (1), 745-753, Fig. 4, full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 386.2
T max /K 1871.8
p min /atm 0.0526
p max /atm 0.0526
INFO BOX
XML file k10001016.xml
File DOI 10.24388/k10001016
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Peeters; G. Mahnen, Symposium (International) on Combustion 1973, 14, (1), 133-146, Fig. 5, k6
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1598.4
T max /K 1911.4
p min /atm 0.0526
p max /atm 0.0526
INFO BOX
XML file k10001017.xml
File DOI 10.24388/k10001017
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. H. Eberius; K. Hoyermann; H. C. Wagner, Symposium (International) on Combustion 1973, 14, (1), 147-156, Fig. 9, open circle, from CO profile
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1117.2
T max /K 1244.3
p min /atm 0.01395
p max /atm 0.01395
INFO BOX
XML file k10001018.xml
File DOI 10.24388/k10001018
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. H. Eberius; K. Hoyermann; H. C. Wagner, Symposium (International) on Combustion 1973, 14, (1), 147-156, Fig. 9, full circle, from CO2 profile
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + OH = CO2 + H
T min /K 1116.2
T max /K 1244.9
p min /atm 0.01395
p max /atm 0.01395
INFO BOX
XML file k10003001.xml
File DOI 10.24388/k10003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J.F. Bott, N. Cohen, Int. J. Chem. Kinet. 1991, 23, 1075-1094, see text
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 1204
T max /K 1204
p min /atm 1
p max /atm 1
INFO BOX
XML file k10003002.xml
File DOI 10.24388/k10003002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S1, X_C2H5OH = 9.383e-5, X_tBH Sol`n = 2.536e-5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 1022
T max /K 1297
p min /   
p max /   
INFO BOX
XML file k10003003.xml
File DOI 10.24388/k10003003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S1, X_C2H5OH = 9.383e-5, X_tBH Sol`n = 2.536e-5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 1045
T max /K 1283
p min /   
p max /   
INFO BOX
XML file k10003004.xml
File DOI 10.24388/k10003004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S1, X_C2H5OH = 4.885e-5, X_tBH Sol`n = 1.394e-5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 857
T max /K 951
p min /   
p max /   
INFO BOX
XML file k10003007.xml
File DOI 10.24388/k10003007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography W.P. Hess, F.P. Tully, Chem. Phys. Lett. (1988), 152, 183-189, Table 1, 16OH
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CH2O+H2O
T min /K 677
T max /K 749.5
p min /   
p max /   
INFO BOX
XML file k10003008.xml
File DOI 10.24388/k10003008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography W.P. Hess, F.P. Tully, Chem. Phys. Lett. (1988), 152, 183-189, Table 1, 18OH, only 599 K data point
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 295
T max /K 599
p min /   
p max /   
INFO BOX
XML file k10003009.xml
File DOI 10.24388/k10003009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. Lorenz, D. Rhaesa, R. Zellner, private communication (1984), in: R. Atkinson, Chem. Rev. 86 (1986) 69, Fig. 72, cross
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 296
T max /K 612
p min /   
p max /   
INFO BOX
XML file k10003010.xml
File DOI 10.24388/k10003010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S.A. Carr, M.A. Blitz, P.W. Seakins, J Chem. Phys. A 115 (2011) 3335-3345, Table 1, CH3CH2OH
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 298
T max /K 523
p min /   
p max /   
INFO BOX
XML file k10003011.xml
File DOI 10.24388/k10003011
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S.A. Carr, M.A. Blitz, P.W. Seakins, J Chem. Phys. A 115 (2011) 3335-3345, Table 3, OH + CH3CH2OH (sorted)
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CH2O+H2O
T min /K 658
T max /K 864
p min /   
p max /   
INFO BOX
XML file k10003012.xml
File DOI 10.24388/k10003012
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography I. Stranic, G.A. Pang, R.K. Hanson, D.M. Golden, C.T. Bowman, J. Chem. Phys. A 118 (2014) 822-828, Table 1
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=PRODUCTS
T min /K 917
T max /K 1263
p min /atm 0.98
p max /atm 1.23
INFO BOX
XML file k10003013.xml
File DOI 10.24388/k10003013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography I. Stranic, G.A. Pang, R.K. Hanson, D.M. Golden, C.T. Bowman, J. Chem. Phys. A 118 (2014) 822-828, Table 2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CH2O+H2O
T min /K 910
T max /K 1274
p min /atm 0.85
p max /atm 1.29
INFO BOX
XML file k10005001.xml
File DOI 10.24388/k10005001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography F.P. Tully, Chem. Phys. Lett., 143, 5, 510-514, Table 1
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=C2H3+H2O
T min /K 651
T max /K 901
p min /   
p max /   
INFO BOX
XML file k10005002.xml
File DOI 10.24388/k10005002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A. Bhargava, P.R. Westmoreland, Combust. Flame, 1998, 113, 333-347, Fig. 16, open circle
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=C2H3+H2O
T min /K 1448.5
T max /K 1745.5
p min /   
p max /   
INFO BOX
XML file k13002001.xml
File DOI 10.24388/k13002001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N.K. Srinivasan, M.-C. Su, J.V. Michael, J. Phys. Chem. A 111 (2007) 3951-3958, Table 4, k4
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+OH=S-CH2+H2O
T min /K 1085
T max /K 1348
p min /   
p max /   
INFO BOX
XML file k20001001.xml
File DOI 10.24388/k20001001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Y. Hidaka; T. Taniguchi; T. Kamesawa; H. Masaoka; K. Inami; H. Kawano, International Journal of Chemical Kinetics 1993, 25, (4), 305-322, Fig. 3, open circle, full square, open triangle, full circle and half-open circles
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP HCO + M = CO + H + M
T min /K 1368.266
T max /K 1906.12
p min /   
p max /   
INFO BOX
XML file k20001002.xml
File DOI 10.24388/k20001002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography I. M. Campbell; B. J. Handy, Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry in Condensed Phases 1978, 74, 316-325, Table 1, M = N2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + H + M = HCO + M
T min /K 425
T max /K 425
p min /Pa 348.1
p max /Pa 1021.2
INFO BOX
XML file k20001003.xml
File DOI 10.24388/k20001003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography I. M. Campbell; B. J. Handy, Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry in Condensed Phases 1978, 74, 316-325, Table 1, M = Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + H + M = HCO + M
T min /K 425
T max /K 425
p min /Pa 409.9
p max /Pa 462.9
INFO BOX
XML file k20001004.xml
File DOI 10.24388/k20001004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. S. Timonen; E. Ratajczak; D. Gutman; A. F. Wagner, The Journal of Physical Chemistry 1987, 91, (20), 5325-5332, Table I, M = He
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP HCO + M = CO + H + M
T min /K 644
T max /K 832
p min /   
p max /   
INFO BOX
XML file k20001005.xml
File DOI 10.24388/k20001005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. S. Timonen; E. Ratajczak; D. Gutman; A. F. Wagner, The Journal of Physical Chemistry 1987, 91, (20), 5325-5332, Table I, M = N2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP HCO + M = CO + H + M
T min /K 643
T max /K 780
p min /   
p max /   
INFO BOX
XML file k20001006.xml
File DOI 10.24388/k20001006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. S. Timonen; E. Ratajczak; D. Gutman; A. F. Wagner, The Journal of Physical Chemistry 1987, 91, (20), 5325-5332, Table I, M = Ar
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP HCO + M = CO + H + M
T min /K 637
T max /K 780
p min /   
p max /   
INFO BOX
XML file k20001007.xml
File DOI 10.24388/k20001007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography G. Friedrichs; J. T. Herbon; D. F. Davidson; R. K. Hanson, Physical Chemistry Chemical Physics 2002, 4, (23), 5778-5788, Fig. 10, open circle and open diamond; not all data points could be digitized
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LP HCO + M = CO + H + M
T min /K 834.82
T max /K 1230.03
p min /   
p max /   
INFO BOX
XML file k20001008.xml
File DOI 10.24388/k20001008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 1
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 590
T max /K 590
p min /Pa 1950020
p max /Pa 13920120
INFO BOX
XML file k20001009.xml
File DOI 10.24388/k20001009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 2
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 643
T max /K 643
p min /Pa 110020
p max /Pa 11350300
INFO BOX
XML file k20001010.xml
File DOI 10.24388/k20001010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 3
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 700
T max /K 700
p min /Pa 150070
p max /Pa 9130150
INFO BOX
XML file k20001011.xml
File DOI 10.24388/k20001011
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 4
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 752
T max /K 752
p min /Pa 110020
p max /Pa 4630230
INFO BOX
XML file k20001012.xml
File DOI 10.24388/k20001012
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 800
T max /K 800
p min /Pa 110050
p max /Pa 12410290
INFO BOX
XML file k20001013.xml
File DOI 10.24388/k20001013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography H. Hippler; N. Krasteva; F. Striebel, Physical Chemistry Chemical Physics 2004, 6, (13), 3383-3388, Supplementary Material, Table 6
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 700
T max /K 700
p min /Pa 110050
p max /Pa 1400160
INFO BOX
XML file k20001014.xml
File DOI 10.24388/k20001014
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography L. N. Krasnoperov; E. N. Chesnokov; H. Stark; A. R. Ravishankara, The Journal of Physical Chemistry A 2004, 108, (52), 11526-11536, Table 1, low pressure data points only
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 498
T max /K 769
p min /bar 0.82
p max /bar 1.5
INFO BOX
XML file k20001015.xml
File DOI 10.24388/k20001015
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography L. N. Krasnoperov; E. N. Chesnokov; H. Stark; A. R. Ravishankara, The Journal of Physical Chemistry A 2004, 108, (52), 11526-11536, Table 1, high pressure data points only
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HCO + M = CO + H + M
T min /K 555
T max /K 715
p min /bar 10
p max /bar 100
INFO BOX
XML file k20003001.xml
File DOI 10.24388/k20003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Herzler, J.A. Manion, W. Tsang, J. Phys. Chem. A, 101 (1997), 6600-5508, Fig. 7
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=PRODUCTS
T min /K 1212.7
T max /K 1275.4
p min /bar 1.75
p max /bar 1.75
INFO BOX
XML file k20003002.xml
File DOI 10.24388/k20003002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R. Chen, J. Chen, M.C. Lin, Experimental and Computational Studies of the Unimolecular Decomposition of Ethanol, 2001 Eastern States Section Fall Technical Meeting, Dec. 4-7, 2001. Data taken from: J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Fig. 4a, full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HPC2H5OH(+M)=C2H4+H2O(+M)
T min /K 839.7
T max /K 889.4
p min /   
p max /   
INFO BOX
XML file k20003003.xml
File DOI 10.24388/k20003003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R. Chen, J. Chen, M.C. Lin, Experimental and Computational Studies of the Unimolecular Decomposition of Ethanol, 2001 Eastern States Section Fall Technical Meeting, Dec. 4-7, 2001. Data taken from: J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Fig. 4a, open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HPC2H5OH(+M)=C2H4+H2O(+M)
T min /K 1321.2
T max /K 1894.7
p min /   
p max /   
INFO BOX
XML file k20003004.xml
File DOI 10.24388/k20003004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R. Chen, J. Chen, M.C. Lin, Experimental and Computational Studies of the Unimolecular Decomposition of Ethanol, 2001 Eastern States Section Fall Technical Meeting, Dec. 4-7, 2001. Data taken from: J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Fig. 4b, open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HPC2H5OH(+M)=CH3+CH2OH(+M)
T min /K 1321.2
T max /K 1894.7
p min /   
p max /   
INFO BOX
XML file k20003005.xml
File DOI 10.24388/k20003005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Li, A. Kazakov, F.L. Dryer, J. Phys. Chem. A, 108 (2004), 7671-7680, Fig. 5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 1045
T max /K 1078
p min /atm 2.35
p max /atm 2.35
INFO BOX
XML file k20003006.xml
File DOI 10.24388/k20003006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 6 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 1381
T max /K 1732
p min /atm 0.199
p max /atm 0.281
INFO BOX
XML file k20003007.xml
File DOI 10.24388/k20003007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 11 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 1361
T max /K 1681
p min /atm 0.356
p max /atm 0.496
INFO BOX
XML file k20003008.xml
File DOI 10.24388/k20003008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 16 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 1308
T max /K 1626
p min /atm 0.492
p max /atm 0.785
INFO BOX
XML file k20003009.xml
File DOI 10.24388/k20003009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, C2H4+H2O branch, all data around 31 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 1318
T max /K 1601
p min /atm 0.949
p max /atm 1.284
INFO BOX
XML file k20003010.xml
File DOI 10.24388/k20003010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 6 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 1381
T max /K 1732
p min /atm 0.199
p max /atm 0.281
INFO BOX
XML file k20003011.xml
File DOI 10.24388/k20003011
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 11 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 1361
T max /K 1681
p min /atm 0.356
p max /atm 0.496
INFO BOX
XML file k20003012.xml
File DOI 10.24388/k20003012
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 16 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 1308
T max /K 1626
p min /atm 0.492
p max /atm 0.785
INFO BOX
XML file k20003013.xml
File DOI 10.24388/k20003013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J.V. Michael, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table S4, CH3+CH2OH branch, all data around 31 Torr
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 1318
T max /K 1601
p min /atm 0.949
p max /atm 1.284
INFO BOX
XML file k20003014.xml
File DOI 10.24388/k20003014
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-W. Wu, H. Matsui, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 115 (2011), 8086-8092, Table 1A
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=PRODUCTS
T min /K 1461
T max /K 1659
p min /atm 0.99
p max /atm 0.99
INFO BOX
XML file k20003015.xml
File DOI 10.24388/k20003015
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-W. Wu, H. Matsui, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 115 (2011), 8086-8092, Table 1B
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=PRODUCTS
T min /K 1449
T max /K 1662
p min /atm 1.45
p max /atm 1.45
INFO BOX
XML file k20003016.xml
File DOI 10.24388/k20003016
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-W. Wu, H. Matsui, N.-S. Wang, M.C. Lin, J. Phys. Chem. A 115 (2011), 8086-8092, Table 1C
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=PRODUCTS
T min /K 1476
T max /K 1661
p min /atm 2.02
p max /atm 2.02
INFO BOX
XML file k30003001.xml
File DOI 10.24388/k30003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K.M. Bansal, G.R. Freeman, J. Amer. Chem. Soc. 90 (1968), 7183-7189, Table II.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+CH3=CH3CHOH+CH4
T min /K 423
T max /K 423
p min /   
p max /   
INFO BOX
XML file k30005001.xml
File DOI 10.24388/k30005001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
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Bibliography N.K. Srinivasan, M.-C. Su, J.V. Michael, Phys. Chem. Chem. Phys. 9 (2007) 4155-4163, Table 4
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 1463
T max /K 1931
p min /atm 0.254
p max /atm 0.771
INFO BOX
XML file k30005002.xml
File DOI 10.24388/k30005002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S.S. Vasu, Z. Hong, D.F. Davidson, R.K. Hanson, D.M. Golden, J. Phys. Chem. A 114 (2010), 11529-11537, Table 2
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 973
T max /K 1438
p min /atm 1.99
p max /atm 10.2
INFO BOX
XML file k30005003.xml
File DOI 10.24388/k30005003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 1 bar series
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 659
T max /K 814
p min /   
p max /   
INFO BOX
XML file k30005004.xml
File DOI 10.24388/k30005004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 15 bar series
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 659
T max /K 805
p min /   
p max /   
INFO BOX
XML file k30005005.xml
File DOI 10.24388/k30005005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 40 bar series
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 300
T max /K 600
p min /   
p max /   
INFO BOX
XML file k30005006.xml
File DOI 10.24388/k30005006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. Fulle, H.F. Hamann, H. Hippler, C.P. Jaensch, Ber. Bunsenges. Phys. Chem. 101 (1997) 1433-1442, Table 2, 139 bar series
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 650
T max /K 798
p min /   
p max /   
INFO BOX
XML file k30005008.xml
File DOI 10.24388/k30005008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Zellner, K. Lorenz, J. Phys. Chem. 88 (1984) 984-989, high-pressure limits extracted from page 987
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 296
T max /K 524
p min /   
p max /   
INFO BOX
XML file k30005009.xml
File DOI 10.24388/k30005009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Atkinson, R.A. Perry, J.N. Pitts Jr., J. Chem. Phys. 66 (1977) 1197-1201, Table 1, high pressure rate constants (least square average of data at p .ge. 225 Torr)
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=PRODUCTS
T min /K 299.2
T max /K 425.1
p min /   
p max /   
INFO BOX
XML file k40001002.xml
File DOI 10.24388/k40001002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Fujii; T. Kakuda; N. Takeishi; H. Miyama, The Journal of Physical Chemistry 1987, 91, (8), 2144-2148, Table II.
Reference DOI TO DO
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Reference figure TO DO
Initial composition N2O CO Ar He
Experimental type  
Apparatus  
Reaction LP CO+O(+M) = CO2(+M)
T min /K 1701
T max /K 2484
p min /atm 2.21
p max /atm 3.75
INFO BOX
XML file k40001003.xml
File DOI 10.24388/k40001003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A. M. Dean; D. C. Steiner, The Journal of Chemical Physics 1977, 66, (2), 598-604, Table I.
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Reference figure TO DO
Initial composition N2O CO Ar
Experimental type  
Apparatus  
Reaction LP CO+O(+M) = CO2(+M)
T min /K 2135
T max /K 3190
p min /atm 0.843
p max /atm 3.024
INFO BOX
XML file k50001001.xml
File DOI 10.24388/k50001001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. Thielen; P. Roth, Ber. Bunsenges. Phys. Chem 1983, 87, 920-925, Fig. 10, all shapes
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CO + O2 = CO2 + O
T min /K 1711
T max /K 3516
p min /   
p max /   
INFO BOX
XML file k50002001.xml
File DOI 10.24388/k50002001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography M. Brouard, M.T. Macpherson, M.J. Pilling, J.M. Tulloch, A.P. Williamson, Chem. Phys. Lett. 113 (1985), 413-418, Table 1
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+H(+M)=CH4(+M)
T min /K 504
T max /K 504
p min /Torr 25.2
p max /Torr 400.2
INFO BOX
XML file k50002006.xml
File DOI 10.24388/k50002006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography M. Brouard, M.T. Macpherson, M.J. Pilling, J. Phys. Chem. 93 (1989) 4047-4059, Table 1, 401 K series
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+H(+M)=CH4(+M)
T min /K 401
T max /K 401
p min /Torr 25.2
p max /Torr 610.5
INFO BOX
XML file k50002007.xml
File DOI 10.24388/k50002007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography M. Brouard, M.T. Macpherson, M.J. Pilling, J. Phys. Chem. 93 (1989) 4047-4059, Table 1, 504 K series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+H(+M)=CH4(+M)
T min /K 504
T max /K 504
p min /Torr 25.2
p max /Torr 611.7
INFO BOX
XML file k50002008.xml
File DOI 10.24388/k50002008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography M. Brouard, M.T. Macpherson, M.J. Pilling, J. Phys. Chem. 93 (1989) 4047-4059, Table 1, 601 K series
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+H(+M)=CH4(+M)
T min /K 601
T max /K 601
p min /Torr 105.3
p max /Torr 711
INFO BOX
XML file k50002101.xml
File DOI 10.24388/k50002101
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J.W. Sutherland, M.-C. Su, J.V. Michael, Int. J. Chem. Kinet. 33 (2001), 669-684, Table IV
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 1738
T max /K 2069
p min /   
p max /   
INFO BOX
XML file k50002102.xml
File DOI 10.24388/k50002102
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography T. Koike, M. Kudo, I. Maeda, H. Yamada, Int. J. Chem. Kinet. 32 (2000), 1-16, Fig. 3, open symbols
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 1868
T max /K 2490.7
p min /   
p max /   
INFO BOX
XML file k50002103.xml
File DOI 10.24388/k50002103
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J.H. Kiefer, S.S. Kumaran, J. Phys. Chem 97 (1993), 414-420, Table I, Kr data
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 2790
T max /K 4466
p min /   
p max /   
INFO BOX
XML file k50002104.xml
File DOI 10.24388/k50002104
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J.H. Kiefer, S.S. Kumaran, J. Phys. Chem 97 (1993), 414-420, Table I, Ar data
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 3079
T max /K 4060
p min /   
p max /   
INFO BOX
XML file k50002107.xml
File DOI 10.24388/k50002107
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D.F. Davidson, M.D. Di Rosa, A.Y. Chang, R.K. Hanson, C.T. Bowman, Proc. Combust. Inst. 24 (1992), 589-596, Table II
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 1790
T max /K 2326
p min /   
p max /   
INFO BOX
XML file k50002108.xml
File DOI 10.24388/k50002108
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography P. Roth, Th. Just, Ber. Bunsenges. Phys. Chem. 79 (1975) 682-686, Fig. 3
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Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 1805.5
T max /K 2293.4
p min /   
p max /   
INFO BOX
XML file k50002109.xml
File DOI 10.24388/k50002109
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography K. Tabayashi, S.H. Bauer, Combust. Flame 34 (1979), 63-83, Table 1
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 1948
T max /K 2773
p min /   
p max /   
INFO BOX
XML file k50002110.xml
File DOI 10.24388/k50002110
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography W.M. Heffington, G.E. Parks, K.G.P. Sulzmann, S.S. Penner, Proc. Combust. Inst. 16 (1977) 997-1011, Fig. 3
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH4(+M)=CH3+H(+M)
T min /K 2022.5
T max /K 2721
p min /   
p max /   
INFO BOX
XML file k50002111.xml
File DOI 10.24388/k50002111
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 995 K series
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH4(+M)=CH3+H(+M)
T min /K 995
T max /K 995
p min /Torr 51
p max /Torr 741
INFO BOX
XML file k50002112.xml
File DOI 10.24388/k50002112
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 1038 K series
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH4(+M)=CH3+H(+M)
T min /K 1038
T max /K 1038
p min /Torr 32
p max /Torr 742
INFO BOX
XML file k50002113.xml
File DOI 10.24388/k50002113
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 1068 K series
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH4(+M)=CH3+H(+M)
T min /K 1068
T max /K 1068
p min /Torr 25
p max /Torr 742
INFO BOX
XML file k50002114.xml
File DOI 10.24388/k50002114
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C.-J. Chen, M.H. Back, R.A, Back, Can. J. Chem. 53 (1975), 3580-3590, Table 3, 1103 K series
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH4(+M)=CH3+H(+M)
T min /K 1103
T max /K 1103
p min /Torr 49
p max /Torr 743
INFO BOX
XML file k70002201.xml
File DOI 10.24388/k70002201
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Z. Hong, D.F. Davidson, K.-Y. Lam, R.K. Hanson, Combust. Flame 159 (2012), 3007-3013, Table 1, k1
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+HO2=CH3O+OH
T min /K 1054
T max /K 1249
p min /   
p max /   
INFO BOX
XML file k70002202.xml
File DOI 10.24388/k70002202
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J.J. Scire Jr., R.A. Yetter, F.L. Dryer, Int. J. Chem. Kinet. 33 (2001), 75-100, Table II, k1
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+HO2=CH3O+OH
T min /K 1000
T max /K 1000
p min /   
p max /   
INFO BOX
XML file k70002301.xml
File DOI 10.24388/k70002301
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Yan, L.N. Krasnoperov, Reactions of CH3 radicals with HO2, International Conference on Chemical Kinetics 2015, Ghent, Belgium, Lecture O21, Fig. 1, digitized
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+HO2=PRODUCTS
T min /K 414
T max /K 414
p min /   
p max /   
INFO BOX
XML file t10003001.xml
File DOI 10.24388/t10003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, alpha-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CHOH+H2O
T min /K 200
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t10003002.xml
File DOI 10.24388/t10003002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, beta-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=C2H4OH+H2O
T min /K 200
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t10003003.xml
File DOI 10.24388/t10003003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, OH-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CH2O+H2O
T min /K 200
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t10003004.xml
File DOI 10.24388/t10003004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Zheng, D.G. Truhlar, Faraday Discuss. (2012), 157, 59-88, alpha-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CHOH+H2O
T min /K 200
T max /K 2400
p min /   
p max /   
INFO BOX
XML file t10003005.xml
File DOI 10.24388/t10003005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Zheng, D.G. Truhlar, Faraday Discuss. (2012), 157, 59-88, beta-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=C2H4OH+H2O
T min /K 200
T max /K 2400
p min /   
p max /   
INFO BOX
XML file t10003006.xml
File DOI 10.24388/t10003006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Zheng, D.G. Truhlar, Faraday Discuss. (2012), 157, 59-88, OH-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CH2O+H2O
T min /K 200
T max /K 2400
p min /   
p max /   
INFO BOX
XML file t10003007.xml
File DOI 10.24388/t10003007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166, alpha-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CHOH+H2O
T min /K 200
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t10003008.xml
File DOI 10.24388/t10003008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166, beta-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=C2H4OH+H2O
T min /K 200
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t10003009.xml
File DOI 10.24388/t10003009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S. Xu, M.C. Lin, Proc. Combust. Inst. 31 (2007), 159-166, OH-site abstraction branch
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+OH=CH3CH2O+H2O
T min /K 200
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t10005001.xml
File DOI 10.24388/t10005001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R.S. Zhu, J. Park, M.C. Lin, Chem. Phys. Lett. 408 (2005), 25-30, digitized from Fig. 4, k3
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=C2H3+H2O
T min /K 300
T max /K 3000
p min /Torr 500
p max /Torr 500
INFO BOX
XML file t10005002.xml
File DOI 10.24388/t10005002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography G.X. Liu, Y.H. Ding, Z.S. Li, Q. Fu, X.R. Huang, C.C. Sun, A.C. Tang, Phys. Chem. Chem. Phys. 4 (2002), 1021-1027, Table 3, CVT/SCT
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=C2H3+H2O
T min /K 200
T max /K 5000
p min /   
p max /   
INFO BOX
XML file t10005003.xml
File DOI 10.24388/t10005003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography S.S. Vasu, Z. Hong, D.F. Davidson, R.K. Hanson, D.M. Golden, J. Phys. Chem. A 114 (2010), 11529-11537, Eq. 2
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=C2H3+H2O
T min /K 600
T max /K 2000
p min /   
p max /   
INFO BOX
XML file t10005004.xml
File DOI 10.24388/t10005004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J.P. Senosiain, S.J. Klippenstein, J.A. Miller, J. Phys. Chem. A 110 (2006), 6960-6970, Table 6, H2O+CHCH2
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H4+OH=C2H3+H2O
T min /K 250
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t13002001.xml
File DOI 10.24388/t13002001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A.W. Jasper, S.J. Klippenstein, L.B. Harding, B. Ruscic, J. Phys. Chem. A 111 (2007) 3932-3950, Table 3
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction CH3+OH=S-CH2+H2O
T min /K 496.69
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t20003001.xml
File DOI 10.24388/t20003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 800
T max /K 2000
p min /atm 0.001
p max /atm 0.001
INFO BOX
XML file t20003002.xml
File DOI 10.24388/t20003002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 800
T max /K 2000
p min /atm 0.01
p max /atm 0.01
INFO BOX
XML file t20003003.xml
File DOI 10.24388/t20003003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 800
T max /K 2000
p min /atm 0.1
p max /atm 0.1
INFO BOX
XML file t20003004.xml
File DOI 10.24388/t20003004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 800
T max /K 2000
p min /atm 1
p max /atm 1
INFO BOX
XML file t20003005.xml
File DOI 10.24388/t20003005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 800
T max /K 2000
p min /atm 10
p max /atm 10
INFO BOX
XML file t20003006.xml
File DOI 10.24388/t20003006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 800
T max /K 2000
p min /atm 100
p max /atm 100
INFO BOX
XML file t20003007.xml
File DOI 10.24388/t20003007
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 800
T max /K 2000
p min /atm 0.001
p max /atm 0.001
INFO BOX
XML file t20003008.xml
File DOI 10.24388/t20003008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 800
T max /K 2000
p min /atm 0.01
p max /atm 0.01
INFO BOX
XML file t20003009.xml
File DOI 10.24388/t20003009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 800
T max /K 2000
p min /atm 0.1
p max /atm 0.1
INFO BOX
XML file t20003010.xml
File DOI 10.24388/t20003010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 800
T max /K 2000
p min /atm 1
p max /atm 1
INFO BOX
XML file t20003011.xml
File DOI 10.24388/t20003011
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 800
T max /K 2000
p min /atm 10
p max /atm 10
INFO BOX
XML file t20003012.xml
File DOI 10.24388/t20003012
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 800
T max /K 2000
p min /atm 100
p max /atm 100
INFO BOX
XML file t20003013.xml
File DOI 10.24388/t20003013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 800
T max /K 2000
p min /atm 0.001
p max /atm 0.001
INFO BOX
XML file t20003014.xml
File DOI 10.24388/t20003014
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 800
T max /K 2000
p min /atm 0.01
p max /atm 0.01
INFO BOX
XML file t20003015.xml
File DOI 10.24388/t20003015
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 800
T max /K 2000
p min /atm 0.1
p max /atm 0.1
INFO BOX
XML file t20003016.xml
File DOI 10.24388/t20003016
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 800
T max /K 2000
p min /atm 1
p max /atm 1
INFO BOX
XML file t20003017.xml
File DOI 10.24388/t20003017
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 800
T max /K 2000
p min /atm 10
p max /atm 10
INFO BOX
XML file t20003018.xml
File DOI 10.24388/t20003018
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, M.-C. Su, J. V. Michael, S. J. Klippenstein, L. B. Harding, B. Ruscic, J. Phys. Chem. A 114 (2010), 9425-9439, Table 5
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 800
T max /K 2000
p min /atm 100
p max /atm 100
INFO BOX
XML file t20003019.xml
File DOI 10.24388/t20003019
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 700
T max /K 2500
p min /atm 0.00000001
p max /atm 0.00000001
INFO BOX
XML file t20003020.xml
File DOI 10.24388/t20003020
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 700
T max /K 2500
p min /atm 1
p max /atm 1
INFO BOX
XML file t20003021.xml
File DOI 10.24388/t20003021
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H4+H2O(+M)
T min /K 700
T max /K 2500
p min /atm 10
p max /atm 10
INFO BOX
XML file t20003022.xml
File DOI 10.24388/t20003022
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k1
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HPC2H5OH(+M)=C2H4+H2O(+M)
T min /K 700
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t20003023.xml
File DOI 10.24388/t20003023
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 700
T max /K 2500
p min /atm 0.00000001
p max /atm 0.00000001
INFO BOX
XML file t20003024.xml
File DOI 10.24388/t20003024
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 700
T max /K 2500
p min /atm 1
p max /atm 1
INFO BOX
XML file t20003025.xml
File DOI 10.24388/t20003025
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=CH3+CH2OH(+M)
T min /K 700
T max /K 2500
p min /atm 10
p max /atm 10
INFO BOX
XML file t20003026.xml
File DOI 10.24388/t20003026
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction HPC2H5OH(+M)=CH3+CH2OH(+M)
T min /K 700
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t20003027.xml
File DOI 10.24388/t20003027
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 700
T max /K 2500
p min /atm 0.00000001
p max /atm 0.00000001
INFO BOX
XML file t20003028.xml
File DOI 10.24388/t20003028
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 700
T max /K 2500
p min /atm 1
p max /atm 1
INFO BOX
XML file t20003029.xml
File DOI 10.24388/t20003029
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH(+M)=C2H5+OH(+M)
T min /K 700
T max /K 2500
p min /atm 10
p max /atm 10
INFO BOX
XML file t20003030.xml
File DOI 10.24388/t20003030
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, R.S. Zhu, M.C. Lin, J. Chem. Phys., 117 (2002), 3224-3231, Table II, k2
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction HPC2H5OH(+M)=C2H5+OH(+M)
T min /K 700
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t30003001.xml
File DOI 10.24388/t30003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography X.F. Xu, J. Park, M.C. Lin, J. Chem. Phys. 120 (2004), 6593-6599, Table II, k1a
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+CH3=CH3CHOH+CH4
T min /K 600
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t30003002.xml
File DOI 10.24388/t30003002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography X.F. Xu, J. Park, M.C. Lin, J. Chem. Phys. 120 (2004), 6593-6599, Table II, k2a
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+CH3=CH3CH2O+CH4
T min /K 600
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t30003003.xml
File DOI 10.24388/t30003003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography X.F. Xu, J. Park, M.C. Lin, J. Chem. Phys. 120 (2004), 6593-6599, Table II, k3a
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+CH3=CH2CH2OH+CH4
T min /K 600
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t50002001.xml
File DOI 10.24388/t50002001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
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Bibliography J. Troe, V.G. Ushakov, J. Chem. Phys. 136 (2012) 214309, see text
Reference DOI TO DO
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Initial composition  
Experimental type  
Apparatus  
Reaction LPCH3+H(+M)=CH4(+M)
T min /K 300
T max /K 5000
p min /   
p max /   
INFO BOX
XML file t50002002.xml
File DOI 10.24388/t50002002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Troe, V.G. Ushakov, J. Chem. Phys. 136 (2012) 214309, see text
Reference DOI TO DO
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Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction LPCH3+H(+M)=CH4(+M)
T min /K 300
T max /K 5000
p min /   
p max /   
INFO BOX
XML file t50003001.xml
File DOI 10.24388/t50003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography R. Sivaramakrishnan, J.V. Michael, S.J. Klippenstein, J. Phys. Chem. A 144 (2010), 755-764, Table 5
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3CHO+H=CH3CO+H2
T min /K 200
T max /K 2500
p min /   
p max /   
INFO BOX
XML file t60003001.xml
File DOI 10.24388/t60003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography J. Park, Y.F. Xu, M.C. Lin, J. Chem. Phys. 118 (2003), 9990-9996, Arrhenius expression found in conclusion
Reference DOI TO DO
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Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction C2H5OH+H=CH3CHOH+H2
T min /K 300
T max /K 3000
p min /   
p max /   
INFO BOX
XML file t70002201.xml
File DOI 10.24388/t70002201
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A.W. Jasper, S.J. Klippenstein, L.B. Harding, Proc. Combust. Inst. 32 (2009), 279-286, see text
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition  
Experimental type  
Apparatus  
Reaction CH3+HO2=CH3O+OH
T min /K 300
T max /K 2500
p min /   
p max /   
INFO BOX
XML file x00000065_p.xml
File DOI 10.24388/x00000065_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1684
T max /K 1855
p min /atm 33
p max /atm 33
INFO BOX
XML file x00000066_p.xml
File DOI 10.24388/x00000066_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1189
T max /K 1300
p min /atm 33
p max /atm 33
INFO BOX
XML file x00000067_p.xml
File DOI 10.24388/x00000067_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1655
T max /K 1930
p min /atm 57
p max /atm 57
INFO BOX
XML file x00000068_p.xml
File DOI 10.24388/x00000068_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1684
T max /K 1779
p min /atm 64
p max /atm 64
INFO BOX
XML file x00000069_p.xml
File DOI 10.24388/x00000069_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1361
T max /K 1876
p min /atm 64
p max /atm 64
INFO BOX
XML file x00000070_p.xml
File DOI 10.24388/x00000070_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1279
T max /K 1344
p min /atm 64
p max /atm 64
INFO BOX
XML file x00000071_p.xml
File DOI 10.24388/x00000071_p
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Davison, D.F., Rohrig, M., Hanson, R.K., Proceedings of the 20th International Symposum on Shock Waves, 1996, 941-946.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1701
T max /K 1715
p min /atm 87
p max /atm 87
INFO BOX
XML file x00000185_p.xml
File DOI 10.24388/x00000185_p
Url link Data web link
File Author Original source: PrIMe Warehouse; Modified at: Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Taylor., S.C., Ph.D. thesis, University of Leeds, 1991.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type laminar burning velocity measurement
Apparatus flame, spherical, premixed, laminar
Reaction  
T min /K 296
T max /K 296
p min /atm 1
p max /atm 1
INFO BOX
XML file x00000356_p.xml
File DOI 10.24388/x00000356_p
Url link Data web link
File Author Original source: PrIMe Warehouse; Modified at: Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Cheng, R.K., Oppenheim, A.K., Combustion and Flame, 1984, (58) 125-139., Fig. 4., open triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1012
T max /K 1427
p min /atm 1.35
p max /atm 2.896
INFO BOX
XML file x00000357_p.xml
File DOI 10.24388/x00000357_p
Url link Data web link
File Author Original source: PrIMe Warehouse; Modified at: Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Cohen, A., Larsen, J., 1967, Report BRL 1386, technical report, original PrIMe file
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 941
T max /K 1583
p min /atm 0.251
p max /atm 1.444
INFO BOX
XML file x00001001.xml
File DOI 10.24388/x00001001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography P. Dagaut; F. Lecomte; J. Mieritz; P. Glarborg, International Journal of Chemical Kinetics 2003, 35, 564-575, Fig. 1a
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1200
p min /atm 1
p max /atm 1
INFO BOX
XML file x00001002.xml
File DOI 10.24388/x00001002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography P. Dagaut; F. Lecomte; J. Mieritz; P. Glarborg, International Journal of Chemical Kinetics 2003, 35, 564-575, Fig. 2a
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1400
p min /atm 1
p max /atm 1
INFO BOX
XML file x00001003_x.xml
File DOI 10.24388/x00001003_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography P. Dagaut; F. Lecomte; J. Mieritz; P. Glarborg, International Journal of Chemical Kinetics 2003, 35, 564-575, Fig. 3a
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 850
T max /K 1400
p min /atm 1
p max /atm 1
INFO BOX
XML file x00003001.xml
File DOI 10.24388/x00003001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 9, C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 890
T max /K 1131
p min /atm 1
p max /atm 1
INFO BOX
XML file x00003002.xml
File DOI 10.24388/x00003002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 8, C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 891
T max /K 1160
p min /atm 1
p max /atm 1
INFO BOX
XML file x00003003.xml
File DOI 10.24388/x00003003
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 6, C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 890
T max /K 1252
p min /atm 1
p max /atm 1
INFO BOX
XML file x00003004.xml
File DOI 10.24388/x00003004
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 7, C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 890
T max /K 1250
p min /atm 1
p max /atm 1
INFO BOX
XML file x00003005_x.xml
File DOI 10.24388/x00003005_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 14, C2H2 and C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 799
T max /K 1040
p min /atm 10
p max /atm 10
INFO BOX
XML file x00003006_x.xml
File DOI 10.24388/x00003006_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 13, C2H2 and C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 801
T max /K 1071
p min /atm 10
p max /atm 10
INFO BOX
XML file x00003007_x.xml
File DOI 10.24388/x00003007_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 11, C2H2 and C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 800
T max /K 1070
p min /atm 10
p max /atm 10
INFO BOX
XML file x00003008_x.xml
File DOI 10.24388/x00003008_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography N. Leplat, P. Dagaut, C. Togbe, J. Vandooren, Combust. Flame 158 (2011) 705-725, Fig. 12, C2H2 and C3H6 not taken
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 801
T max /K 1130
p min /atm 10
p max /atm 10
INFO BOX
XML file x00003009_x.xml
File DOI 10.24388/x00003009_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography B. Aboussi, Ph.D. Dissertation, Orleans, 1991. data from: P. Dagaut, J.C. Boettner, M. Cathonnet, J. Chim. Phys. 89 (1992), 867-884, Fig. 2a (phi=1)
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 1055
T max /K 1060
p min /atm 1
p max /atm 1
INFO BOX
XML file x00003010_x.xml
File DOI 10.24388/x00003010_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography B. Aboussi, Ph.D. Dissertation, Orleans, 1991. data from: P. Dagaut, J.C. Boettner, M. Cathonnet, J. Chim. Phys. 89 (1992), 867-884, Fig. 2b (phi=2)
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition C2H5OH O2 N2
Experimental type jet stirred reactor measurement
Apparatus stirred reactor
Reaction  
T min /K 1064
T max /K 1077
p min /atm 1
p max /atm 1
INFO BOX
XML file x10000001.xml
File DOI 10.24388/x10000001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Skinner G.B., Ringrose G.H., Journal of Chemical Physics, (42) 2190-2192., 1965, Table I.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 964
T max /K 1075
p min /atm 5
p max /atm 5
INFO BOX
XML file x10000002.xml
File DOI 10.24388/x10000002
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Schott G.L., Kinsey J.L., Journal of Chemical Physics, (29), 1177-1182., 1958, Fig. 3., open triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1086
T max /K 1836
p min /atm 0.736
p max /atm 1.989
INFO BOX
XML file x10000005.xml
File DOI 10.24388/x10000005
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Slack M.W., Combustion and Flame, (28), 241-249., 1977, Fig. 2., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 984
T max /K 1184
p min /atm 2
p max /atm 2
INFO BOX
XML file x10000006.xml
File DOI 10.24388/x10000006
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Fujimoto, S., Suzuki, M., Memoirs of the Defense Academy, Japan, 1967, (VII., 3), 1037-1046, Table 1.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 835
T max /K 1335
p min /Torr 685
p max /Torr 1525
INFO BOX
XML file x10000007_x.xml
File DOI 10.24388/x10000007_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Fujimoto, S., Suzuki, M., Memoirs of the Defense Academy, Japan, 1967, (VII., 3), 1037-1046, Table 2.
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 890
T max /K 1076
p min /Torr 1440
p max /Torr 2080
INFO BOX
XML file x10000008.xml
File DOI 10.24388/x10000008
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Kalitan, D.M., Rickard,M.J.A., Proceedings of the Third Joint Meeting of the U.S. Sections of The Combustion Institute, 2003, 1-6., Fig. 2., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1009
T max /K 1431
p min /atm 1
p max /atm 1
INFO BOX
XML file x10000016.xml
File DOI 10.24388/x10000016
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Kalitan, D.M., Rickard,M.J.A., Proceedings of the Third Joint Meeting of the U.S. Sections of The Combustion Institute, 2003, 1-6., Fig. 4., full triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1111
T max /K 1511
p min /atm 1
p max /atm 1
INFO BOX
XML file x10000017_x.xml
File DOI 10.24388/x10000017_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Petersen, E.L., Kalitan, D.M., Rickard,M.J.A., Proceedings of the Third Joint Meeting of the U.S. Sections of The Combustion Institute, 2003, 1-6., Fig. 3., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1181
T max /K 1753
p min /atm 1
p max /atm 1
INFO BOX
XML file x10000019.xml
File DOI 10.24388/x10000019
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Cheng, R.K., Oppenheim, A.K., Combustion and Flame, 1984, (58) 125-139., Fig. 4., open diamond
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1004
T max /K 1397
p min /atm 1.063
p max /atm 2.84
INFO BOX
XML file x10000020.xml
File DOI 10.24388/x10000020
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Bhaskaran K.A., Gupta M.C., Just, T.H., Combustion and Flame, 1973, (21), (1), 45-48., Fig. 4., open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1038
T max /K 1323
p min /atm 2.5
p max /atm 2.5
INFO BOX
XML file x10000021_x.xml
File DOI 10.24388/x10000021_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 8., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1051
T max /K 1272
p min /atm 4
p max /atm 4
INFO BOX
XML file x10000022.xml
File DOI 10.24388/x10000022
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 6., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 955
T max /K 1173
p min /atm 4
p max /atm 4
INFO BOX
XML file x10000023.xml
File DOI 10.24388/x10000023
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 7., full triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 H2O N2
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1011
T max /K 1239
p min /atm 4
p max /atm 4
INFO BOX
XML file x10000024_x.xml
File DOI 10.24388/x10000024_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 9., full diamond
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1075.3
T max /K 1331
p min /atm 4
p max /atm 4
INFO BOX
XML file x10000025.xml
File DOI 10.24388/x10000025
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106., Fig. 10., open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1099
T max /K 1252
p min /atm 9.5
p max /atm 9.5
INFO BOX
XML file x10000026.xml
File DOI 10.24388/x10000026
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Wang B.L., Olivier H.; Grönig H., Combustion and Flame, 2003, (133), (1-2), 93-106.,Fig. 10., crossed X
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2 H2O
Experimental type ignition delay measurement
Apparatus shock tube, reflected shock
Reaction  
T min /K 1049
T max /K 1209
p min /atm 16
p max /atm 16
INFO BOX
XML file x10000027_x.xml
File DOI 10.24388/x10000027_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Asaba T., Gardiner W.C.Jr., Stubbeman R.F., Proceedings of the Combustion Institute, 1965, (10), 295-302., Fig. 6., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, incident shock
Reaction  
T min /K 1428
T max /K 2320
p min /atm 0.233
p max /atm 0.412
INFO BOX
XML file x10000028.xml
File DOI 10.24388/x10000028
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Asaba T., Gardiner W.C.Jr., Stubbeman R.F., Proceedings of the Combustion Institute, 1965, (10), 295-302., Fig. 6., open circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, incident shock
Reaction  
T min /K 1602
T max /K 2554
p min /atm 0.27
p max /atm 0.46
INFO BOX
XML file x10000029_x.xml
File DOI 10.24388/x10000029_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Asaba T., Gardiner W.C.Jr., Stubbeman R.F., Proceedings of the Combustion Institute, 1965, (10), 295-302., Fig. 6., full rectangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube, incident shock
Reaction  
T min /K 1480
T max /K 2423
p min /atm 0.243
p max /atm 0.432
INFO BOX
XML file x10000030_x.xml
File DOI 10.24388/x10000030_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Zhang, Y., Huang, Z., Wei, L., Zhang, J., Law, C.K., Combustion and Flame, (159), 918-931, 2012, Fig. 9., full square
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1023.541
T max /K 1194.743
p min /bar 5
p max /bar 5
INFO BOX
XML file x10000031.xml
File DOI 10.24388/x10000031
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Zhang, Y., Huang, Z., Wei, L., Zhang, J., Law, C.K., Combustion and Flame, (159), 918-931, 2012, Fig. 9., full circle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1035.197
T max /K 1222.494
p min /bar 10
p max /bar 10
INFO BOX
XML file x10000032.xml
File DOI 10.24388/x10000032
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Zhang, Y., Huang, Z., Wei, L., Zhang, J., Law, C.K., Combustion and Flame, (159), 918-931, 2012, Fig. 9., full triangle
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1011.122
T max /K 1267.427
p min /bar 20
p max /bar 20
INFO BOX
XML file x10001001.xml
File DOI 10.24388/x10001001
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography E. L. Petersen; D. M. Kalitan; A. B. Barrett; S. C. Reehal; J. D. Mertens; D. J. Beerer; R. L. Hack; V. G. McDonell, Combustion and Flame 2007, 149, (1-2), 244-247, Table 1, top
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO CO2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 943
T max /K 1148
p min /atm 16.5
p max /atm 32.7
INFO BOX
XML file x10001009.xml
File DOI 10.24388/x10001009
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:5, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1037
T max /K 1255
p min /bar 15.98
p max /bar 17.8
INFO BOX
XML file x10001010.xml
File DOI 10.24388/x10001010
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:5, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 935
T max /K 1360
p min /bar 3.4
p max /bar 4.2
INFO BOX
XML file x10001011.xml
File DOI 10.24388/x10001011
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:5, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 939
T max /K 2109
p min /bar 0.74
p max /bar 1.34
INFO BOX
XML file x10001012_x.xml
File DOI 10.24388/x10001012_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:1, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 956
T max /K 1178
p min /bar 17.54
p max /bar 18.74
INFO BOX
XML file x10001013.xml
File DOI 10.24388/x10001013
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:1, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 932
T max /K 1131
p min /bar 4.12
p max /bar 4.54
INFO BOX
XML file x10001014.xml
File DOI 10.24388/x10001014
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.1, dilution 1:1, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 889
T max /K 1675
p min /bar 0.69
p max /bar 1.22
INFO BOX
XML file x10001015.xml
File DOI 10.24388/x10001015
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 4.0, dilution 1:5, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 947
T max /K 1227
p min /bar 14.2
p max /bar 16.6
INFO BOX
XML file x10001016.xml
File DOI 10.24388/x10001016
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 4.0, dilution 1:5, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 967
T max /K 1463
p min /bar 3.7
p max /bar 4.5
INFO BOX
XML file x10001017.xml
File DOI 10.24388/x10001017
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 4.0, dilution 1:5, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 943
T max /K 2136
p min /bar 0.92
p max /bar 1.37
INFO BOX
XML file x10001018.xml
File DOI 10.24388/x10001018
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.5, dilution 1:5, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1060
T max /K 1243
p min /bar 15.1
p max /bar 16.26
INFO BOX
XML file x10001019_x.xml
File DOI 10.24388/x10001019_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C., Herzler, J., Griebel, P., Curran, H., Keromnes, A., Mantzaras, I., H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.5, dilution 1:5, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1006
T max /K 1257
p min /bar 3.91
p max /bar 4.54
INFO BOX
XML file x10001020.xml
File DOI 10.24388/x10001020
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography Naumann, C., Herzler, J., Griebel, P., Curran, H., Keromnes H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / O2 / Ar, Phi = 0.5, dilution 1:5, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 932
T max /K 1954
p min /bar 0.94
p max /bar 1.05
INFO BOX
XML file x10001021_x.xml
File DOI 10.24388/x10001021_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 5/95, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1040
T max /K 1438
p min /bar 13.4
p max /bar 16.04
INFO BOX
XML file x10001022.xml
File DOI 10.24388/x10001022
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 5/95, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 991
T max /K 1934
p min /bar 3.44
p max /bar 4.25
INFO BOX
XML file x10001023.xml
File DOI 10.24388/x10001023
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 5/95, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 957
T max /K 2374
p min /bar 0.85
p max /bar 1.14
INFO BOX
XML file x10001024_x.xml
File DOI 10.24388/x10001024_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 50/50, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 997
T max /K 1215
p min /bar 14.7
p max /bar 16.84
INFO BOX
XML file x10001025.xml
File DOI 10.24388/x10001025
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 50/50, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 942
T max /K 1364
p min /bar 3.71
p max /bar 5.07
INFO BOX
XML file x10001026.xml
File DOI 10.24388/x10001026
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 1.0, dilution 1:5, H2 /CO = 50/50, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 924
T max /K 2220
p min /bar 0.76
p max /bar 1.18
INFO BOX
XML file x10001027_x.xml
File DOI 10.24388/x10001027_x
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1055
T max /K 1470
p min /bar 15.67
p max /bar 17.02
INFO BOX
XML file x10001028.xml
File DOI 10.24388/x10001028
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1042
T max /K 1824
p min /bar 3.68
p max /bar 4.56
INFO BOX
XML file x10001029.xml
File DOI 10.24388/x10001029
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 5/95, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 943
T max /K 2246
p min /bar 0.89
p max /bar 1.17
INFO BOX
XML file x10001030.xml
File DOI 10.24388/x10001030
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 16 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1007
T max /K 1249
p min /bar 15.06
p max /bar 17.16
INFO BOX
XML file x10001031.xml
File DOI 10.24388/x10001031
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 4 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 970
T max /K 1418
p min /bar 3.6
p max /bar 4.83
INFO BOX
XML file x10001032.xml
File DOI 10.24388/x10001032
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography C. Naumann; J. Herzler; P. Griebel; H. Curran; A. Keromnes; I. Mantzaras H2-IGCC project: Results of ignition delay times for hydrogen-rich and syngas fuel mixtures measured; 2011, Table 3.1, H2 / CO / O2 / Ar, Phi = 0.5, dilution 1:5, H2 /CO = 50/50, 1 bar series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 882
T max /K 2031
p min /bar 0.82
p max /bar 1.12
INFO BOX
XML file x10001033.xml
File DOI 10.24388/x10001033
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 80/20 (mixture 1), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 916
T max /K 1151
p min /atm 0.9
p max /atm 1.2
INFO BOX
XML file x10001034.xml
File DOI 10.24388/x10001034
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 60/40 (mixture 2), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 914
T max /K 1241
p min /atm 1
p max /atm 1.1
INFO BOX
XML file x10001035.xml
File DOI 10.24388/x10001035
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 40/60 (mixture 3), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 900
T max /K 1169
p min /atm 0.9
p max /atm 1.1
INFO BOX
XML file x10001036.xml
File DOI 10.24388/x10001036
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 20/80 (mixture 4), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 934
T max /K 1183
p min /atm 1.1
p max /atm 1.2
INFO BOX
XML file x10001037.xml
File DOI 10.24388/x10001037
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 20/80 (mixture 4), mid pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 929
T max /K 1063
p min /atm 2.5
p max /atm 3.1
INFO BOX
XML file x10001038.xml
File DOI 10.24388/x10001038
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 20/80 (mixture 4), high pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1015
T max /K 1190
p min /atm 13.7
p max /atm 17.9
INFO BOX
XML file x10001039.xml
File DOI 10.24388/x10001039
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 10/90 (mixture 5), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 960
T max /K 1197
p min /atm 1.1
p max /atm 1.2
INFO BOX
XML file x10001040.xml
File DOI 10.24388/x10001040
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 10/90 (mixture 5), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 981
T max /K 1148
p min /atm 2.1
p max /atm 2.7
INFO BOX
XML file x10001041.xml
File DOI 10.24388/x10001041
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 10/90 (mixture 5), high pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1063
T max /K 1265
p min /atm 11.9
p max /atm 17.1
INFO BOX
XML file x10001042.xml
File DOI 10.24388/x10001042
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 5/95 (mixture 6), low pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 968
T max /K 1263
p min /atm 1
p max /atm 1.2
INFO BOX
XML file x10001043.xml
File DOI 10.24388/x10001043
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 5/95 (mixture 6), mid pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 977
T max /K 1304
p min /atm 1.7
p max /atm 2.3
INFO BOX
XML file x10001044.xml
File DOI 10.24388/x10001044
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography D. M. Kalitan; J. D. Mertens; M. W. Crofton; E. L. Petersen, Journal of Propulsion and Power 2007, 23, (6), 1291-1303, Table 2, H2/CO = 5/95 (mixture 6), high pressure series
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 N2
Experimental type ignition delay measurement
Apparatus shock tube
Reaction  
T min /K 1074
T max /K 1163
p min /atm 12.7
p max /atm 19.2
INFO BOX
XML file x10001049.xml
File DOI 10.24388/x10001049
Url link Data web link
File Author Chemical Kinetics Laboratory, Institute of Chemistry, ELTE, Budapest, Hungary
File Version 1.1
ReSpecTh Version 2.0
Bibliography A. M. Dean; D. C. Steiner; E. E. Wang, Combustion and Flame 1978, 32, (0), 73-83, Table 2, mixture C, tau_1 definition
Reference DOI TO DO
Reference location TO DO
Reference table TO DO
Reference figure TO DO
Initial composition H2 CO O2 Ar
Experimental type ignition delay measurement
Apparatu