. Delacroix F., “The flameless oxidation mode,” ADEME (French Agency for energy and environment management).
. Weber R. and Smart J. P., “On the (MILD) combustion of gaseous, liquid, and solid fuels in high temperature preheated air,” Proceedings of the Combustion Institute, Vol. 30: pp. 2623-2629, 2005, .
. He Y., “Flameless combustion of natural gas in the SJ/WJ furnace,” Thesis for Doctor of Philosophy Queen's University 2008.
. Cavaliere A. and De Joannon M., “Mild combustion,” Prog. Energy Combustion Science, Vol. 30: pp. 329-366, 2004.
. Minamoto Y., “Physical aspects and modelling of turbulent MILD combustion,” A Thesis Submitted for the Degree of Doctor of Philosophy at University of Cambridge, 2013.
. Dally B. B., Riesmeier E. and Peters N., “Effect of fuel mixture on moderate and intense low oxygen dillution combustion,” Combustion and Flame, Vol. 137, Issue 4, pp. 418-431 June 2004.
. Oldenhof E., Tummers M. J., van Veen E. H. and Roekaerts D. J. E. M., “Role of entrainment in the stabillisation of jet in hot coflow flames,” Combustion Flame, 158: pp. 1553-1563, 2011.
. Christo F. C. and Dally B. B., “Modeling turbulent reacting jets issuing into a hot and diluted coflow,” Combustion and Flame, Vol. 142, Issues 1–2, pp. 117-129, July 2005.
. Xing F., Kumar A., Huang Y., Chan Sh., Ruan C., Gu S. and Fan X., “Flameless combustion with liquid fuel: A review focusing on fundamentals and gas turbine application,” Applied Energy, pp. 28-51, 2017.
. Tsuji H., A. K. G., Hasegawa T., Katsuki M., Kishimoto K. and Morita M., “High temperature air combustion: from energy conservation to pollution reduction,” in CRC Press. Japan, 2003.
. Li P. F., J. Ch. Mi, Dally B. B., Wang F. F., L. Wang, Liu Zh. H., Chen Sh. and Zheng Ch. G., “Progress and recent trend in MILD combustion,” Sci. China. Technol. Vol. 54, pp. 255-69, 2011.
. Awosope I. O. and F Lockwood. C., “Prediction of combustion and NOx emission characteristics of flameless oxidation combustion,” IFRF Combustion Journal, 2005.
. Wuenning. J. A. W. a. J. G., “Flameless oxidation to reduce thermal NO formation,” Progress in Energy and Combustion Science, Vol. 23, Issue 1, pp. 81-94, 1997.
. Company A. Ansys Documentation, “User guide”.
. Zel'dovich Y. B., “The oxidation of nitrogen in combustion to reduce thermal no-formation,” Acta Physiochimica U.S.S.R., 1946.
. Miller J. A. and Bowman C. T., “Mechanism and modeling of nitrogen chemistry in combustion,” Progress in Energy and Combustion Science, Vol. 15, Issue 4, pp. 287-338, 1989.
. Dagaut P., Glarborg P. and Alzueta M. U., “The oxidation of hydrogen cyanide and related chemistry,” Progress in Energy and Combustion Science, Vol. 34, Issue 1, pp. 1-46, 2008, .
. Hosseini S. E. and Abdul Wahid M., “Investigation of bluff-body micro-flameless combustion,” Energy Conversion and Management, Vol. 88, pp. 120–128, 2014.
. Hosseini S. E., Bagheri G. and Wahid M. A., “Numerical investigation of biogas flameless combustion,” Energy Conversion and Management, Vol. 81: pp. 41-50, 2014.