References
- Peters, N., Donnerhack, S., 1981, “Structure and Similarity of Nitric Oxide Production in Turbulent Diffusion Flames,” Proc Combust Inst, Vol. 18, pp. 33-42
- Drake, M. C., Blint, R. J., 1991, “Relative Importance of Nitric Oxide Formation Mechanisms in Laminar Opposed-flow Diffusion Flames,” Combust Flame, Vol. 83, pp.185-203 https://doi.org/10.1016/0010-2180(91)90212-T
- Chen, R. H., Driscoll, J. F., 1990, “Nitric Oxide Levels of Jet Diffusion Flames : Effects of Coaxial Air and Other Mixing Parameters,” Proc. Combust Inst, Vol. 23, pp.281-8
- Lee, C. E., Hwang, C. H., Lee, S. R., 2007, “The Effect of Turbulence Intensity of Ambient Air Flow on NOx Emissions in H2/air Nonpremixed Jet Flames,” Proc. Int. J. of Hydrogen Energy
- Bozzelli, J. W., Dean, A. M., 1995, “O+NNH : a Possible New Route for NOx Formation in Flames,” Int J Chem Kinet, Vol. 27, pp. 1097-109 https://doi.org/10.1002/kin.550271107
- Haworth, N. L., Mackie, J. C., Bacskay, G. B., 2003, “An Ab Initio Quantum Chemical and Kinetic Study of the NNH+O Reaction Potential Energy Surface: How Important is This Route to NO in Combustion?,” J Phys Chem A, Vol. 107, pp. 6792-803 https://doi.org/10.1021/jp034421p
-
Konnov, A. A., De Ruyck, J., 2001, “Temperaturedependent Rate Constant for the Reaction NNH+O
$\rightarrow$ NH+,” Combust Flame, Vol. 125, pp. 1258-64 https://doi.org/10.1016/S0010-2180(01)00250-4 - Kee, R. J., Miller, J. A., Evans, G. H. and Dixon-Lewis, G., 1988, “A Computational Model of the Structure and Extinction of Strained, Opposed Flow, Premixed Methane-Air Flame,” Proc. Combustion Inst., Vol. 22, pp. 1479-1494
- Lutz, R. J., Dixon-Lewis, G., Warnatz, J., Coltrin, M. E. and Miller, J. A., 1994, “A Fortran Program for Computing Opposed-Flow Diffusion Flames,” SAND 96-8243
- Tien, C. L., 1968, "Thermal Radiation Properties of Gases", Advances in Heat Transfer, Vol. 5, pp. 253-32
- Ju, Y., Guo, H., Maruta, K. and Liu, F., 1997, “On the Extinction Limit and Flammability Limit of Nonadiabatic Stretched Methane-Air Premixed Flames,” J. Fluid Mech., Vol. 342, pp. 315-334 https://doi.org/10.1017/S0022112097005636
- Martin, S., Kjell, E.R., 2007, “A study of NOx Formation in Hydrogen Flames,” International J of Hydrogen Energy, Vol. 32, pp. 3572-585 https://doi.org/10.1016/j.ijhydene.2007.02.038
- Li, J., Zhao, Z., Kazakov, A., Dryer FL, 2004, “An Updated Comprehensive Kinetic Model of Hydrogen,” Int J Chem Kinet Vol. 36, pp. 566-75 https://doi.org/10.1002/kin.20026
- Glaborg, P., Alzueta, M.U., Dam-Johansen, K., Miller, J.A., 1998, “Kenitic Modeling of Hydrocarbon/nitric Oxide Interactions in a Flow Reactor,” Combust Flame Vol. 115, pp. 1-27 https://doi.org/10.1016/S0010-2180(97)00359-3
- Turanyi, T., Kinalc Homepage, http://www.chem-.leeds.ac.uk/Combustion/kinalc.html
- Lutz, A. E., Kee, R. J., Grcar, J. F. and Rupley, F. M.,1997, “OPPDIF: A Fortran Program for Computing Opposed-Flow Diffusion Flames,” SAND 96-8243
- Kee, R. J., Rupley, F. M. and Miller, J. A., 1989, “Chemkin-Ⅱ: A Fortran Chemical Kinetics Package for the Analysis of Gas Phase Chemical Kinetics,” SAND89-8009B
- Kee, R. J., Dixon-Lewis, Warnatz, G. J., Coltrin, M. E. and Miller, J. A., 1994, “A Fortran Computer Code Package for the Evaluation of Gas-Phase Multi-Component Transport,” SAND86-8246
- Takeno, T. and Nishioka, M., 1993, “Species Conservation and Emission Indices for Flames Described by Similarity Solutions,” Comb. Flame, Vol. 92, pp. 465-448 https://doi.org/10.1016/0010-2180(93)90157-X
- Rortveit, G, J., Hustad, J. E., Li, S. C., Williams , F. A., 2002, “Effects of Diluents on NOx Formation in Hydrogen Counterflow Flames”, Combustion and Flames, Vol. 130, pp. 48-61 https://doi.org/10.1016/S0010-2180(02)00362-0