References
- Cong, T. L., and P. Dagaut. 2009. Experimental and detailed modeling study of the effect of water vapor on the kinetics of combustion of hydrogen and natural gas, impact on NOx. Energy & Fuels 23:725–734.
- Glass, J. W., and J. O. L. Wendt. 1982. Mechanisms governing the destruction of nitrogeneous species during the fuel rich combustion of pulverized coal. Symposium on Combustion 19:1243–1251.
- Hill, S. C., and L. D. Smoot. 2000. Modeling of nitrogen oxides formation and destruction in combustion systems. Progress Energy Combustion 26:417–458.
- Javed, M. T., N. Irfan, and B. M. Gibbs. 2007. Control of combustion-generated nitrogen oxides by selective non-catalytic reduction. Journal of Environmental Management 83:251–289.
- Li, S., X. Wei, and X. Guo. 2012. Effect of H2O vapor on NO reduction by CO: Experimental and kinetic modeling study. Energy & Fuels 26:4277–4283.
- Øyvind, S., P. Kilpinen, and P. Glarborg. 2004. Ammonia chemistry below 1400K under fuel-rich conditions in a flow reactor. Combustion Flame 136:501–518.
- Taniguchi, M., Y. Kamikawa, T. Okazaki, K. Yamamoto, and H. Orita. 2010. A role of hydrocarbon reaction for NOx, formation and reduction in fuel-rich pulverized coal combustion. Combustion Flame 157:1456–1466.
- Taniguchi, M., K. Yamamoto, H. Kobayashi, and K. Kiyama. 2002. A reduced NOx reaction model for pulverized coal combustion under fuel-rich conditions. Fuel 81:363–371.
- Zhang, J., T. Ito, T. Okada, E. Oono, and T. Suda. 2013. Improvement of NOx, formation model for pulverized coal combustion by increasing oxidation rate of HCN. Fuel 113:697–706.