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front, especially given that most of the elements involved in the combustion
reaction are light, rendering themselves convenient for theoretical studies.
On the experimental front, ultrafast kinetic studies may help to gain more
and direct insight into the reaction mechanism involving short-lived species,
such as radicals as intermediates.
REFERENCES
1. Mueller, M.A., Kim, T.J., Yetter, R.A., Dryer, F.L. Flo reactor studies and kinetic model-
ing of the H
2
/O
2
reaction.
Int. J. Chem. Kinetics
1999
,
31
, 113-125.
2. Li, J., Zhao, Z.W., Kazakov, A., Dryer, F.L. An updated comprehensive kinetic model of
hydrogen combustion.
International Journal of Chemical Kinetics
2004
,
36
(10),
566-575.
3. Troe, J., Detailed modeling of the temperature and pressure dependence of the reaction
H+O
2
(+M) → HO
2
(+M).
Proc. Combust. Inst
2000
,
28
, 1463-1469.
4. Klell, M., Eichlseder, H., Sartory, M. Mixtures of hydrogen and methane in the internal
combustion engine: Synergies, potential and regulations.
International Journal of Hydro-
gen Energy
2012
,
37
(15), 11531-11540.
5. Frassoldati, A., Faravelli, T., Ranzi, E. A wide range modeling study of NOx formation
and nitrogen chemistry in hydrogen combustion.
International Journal of Hydrogen
Energy
2006
,
31
(15), 2310-2328.
6. Rortveit, G.J., Hustad, J.E., Li, S.C., Williams, F.A. Effects of diluents on NOx formation
in hydrogen counterflow flames.
Combustion and Flame
2002
,
130
(1-2), 48-61.
7. Ayoub, M., Rottier, C., Carpentier, S., Villermaux, C., Boukhalfa, A.M., Honore, D. An
experimental study of mild flameless combustion of methane/hydrogen mixtures.
Inter-
national Journal of Hydrogen Energy
2012
,
37
(8), 6912-6921.
8. Shimizu, K., Hibi, A., Koshi, M., Morii, Y., Tsuboi, N. Updated kinetic mechanism for
high-pressure hydrogen combustion.
Journal of Propulsion and Power
2011
,
27
(2),
383-395.
9. Stamps, D.W., Berman, M. High-temperature hydrogen combustion in reactor safety
applications.
Nuclear Science and Engineering
1991
,
109
(1), 39-48.
10. Sepman, A.V., Mokhov, A.V., Levinsky, H.B. Extending the predictions of chemical
mechanisms for hydrogen combustion: Comparison of predicted and measured flame
temperatures in burner-stabilized, 1-D flames.
International Journal of Hydrogen Energy
2011
,
36
(15), 9298-9303.
11. Haruta, M., Sano, H. Catalytic combustion of hydrogen 1: Its role in hydrogen utilization
system and screening of catalyst materials.
International Journal of Hydrogen Energy
1981
,
6
(6), 601-608.
12. Haruta, M., Souma, Y., Sano, H. Catalytic combustion of hydrogen 2: An experimental
investigation of fundamental conditions for burner design.
International Journal of
Hydrogen Energy
1982
,
7
(9), 729-736.
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