Prof. Dr. Myles D. Bohon

Myles Bohon is a Guest Professor and head of the Pressure Gain Combustion research group at TU Berlin. Prior to that, Myles was a postdoc and research group leader for the development of the rotating detonation engine research group at TUB, resulting in the first demonstration of an RDE in Germany. Myles received his Ph.D. from King Abdullah University of Science and Technology (KAUST) in the Clean Combustion Research Center (CCRC), with a focus on NO_X emissions and formation mechanisms in oxygenated fuels. His current research interests include pressure gain combustion and unsteady reacting flows for innovative and sustainable energy, laser diagnostics for high temporal resolution in-situ measurements, and novel techniques for interpreting and identifying mechanisms in complex networks.

Kontakt

Email: m.bohon@tu-berlin.de

Kurzlebenslauf

• 2019-Jetzt: Gastprofessor, TU Berlin
• 2016-2019: Rotating detonation engine research group leader, TU Berlin
• 2012-2016: Doktorand, KAUST
• 2010-2012: Wissenschaftlicher Mitarbeiter, NCSU
• 2008-2010: Masterstudium, Mechanical Engineering, NCSU
• 2003-2008: Bachelorstudium, Mechanical Engineering, NCSU
• 2003-2008: Bachelorstudium, Business Management, NCSU

Engagements und Aktivitäten

• AIAA Pressure Gain Combustion Technical Committee Member
• AIAA Pressure Gain Combustion TC Best Paper Award Committee Chair
• Organizing Chair, Joint Meeting of the International Workshop on Detonation Propulsion (IWDP) and International Constant Volume and Detonation Combustion Workshop (ICVDCW)
• Technical Discipline Deputy Chair for AIAA SciTech 2021 PGC TC
• Technical Discipline Chair for AIAA SciTech 2022 PGC TC
• INSPIRE ITN Training Supervisory Committee Chair
• Reviewer for Combustion and Flame, Proceedings of the Combustion Institute, AIAA Journal, Flow, Turbulence and Combustion, ASME Journal of Engineering for Gas Turbines and Power, Acta Astronautica, Combustion Science and Technology, Physics of Fluids, etc.

Publikationen [Google Scholar] [ResearchGate]

Pressure Gain Combustion

• Bach, E., Stathopoulos, P., Paschereit, C.O., Bohon, M.D., "Performance analysis of a rotating detonation combustor based on stagnation pressure measurements," Combustion and Flame 217 (2020): pp. 21-36. [link]
• Bluemner, R., Bohon, M.D., Paschereit, C.O., Gutmark, E.J., "Effect of inlet and outlet boundary conditions on rotating detonation combustion," Combustion and Flame 216 (2020): pp. 300-315. [link]
• Weiss, S., Bohon, M.D., Paschereit, C.O., Gutmark, E.J., "Investigation of Reactants Mixing in a Rotating Detonation Combustor Using Compressible RANS," Flow, Turbulence and Combustion 105 (2020): pp. 267-295. [link]
• Bluemner, R., Bohon, M.D., Paschereit, C.O., Gutmark, E.J., "Counter-rotating wave mode transition dynamics in an RDC," International Journal of Hydrogen Energy 44 (2019): pp. 7628-7641. [link]
• Bluemner, R., Bohon, M.D., Paschereit, C.O., Gutmark, E.J., "Experimental study of reactant mixing in model rotating detonation combustor geometries," Flow, Turbulence and Combustion 102(2019): pp. 255-277. [link]
• Bohon, M.D., Bluemner, R., Paschereit, C.O., Gutmark, E.J., "High-speed imaging of wave modes in an RDC," Experimental Thermal and Fluid Science 102 (2019): pp. 28-37. [link]
• Bohon, M.D., Bluemner, R., Paschereit, C.O., Gutmark, E.J., "Measuring Rotating Detonation Combustion Using Cross-Correlation," Flow, Turbulence and Combustion 103 (2019): pp. 271-292. [link]
• Bach, E., Paschereit, C.O., Stathopoulos, P., Bohon, M.D., "An empirical model for stagnation pressure gain in rotating detonation combustors," Proceedings of the Combustion Institute (Accepted) (2020): pp. XXX-XXX. [link]
• Bluemner, R., Gutmark, E.J., Paschereit, C.O., Bohon, M.D., "Stabilization mechanisms of longitudinal pulsations in rotating detonation combustors," Proceedings of the Combustion Institute (Accepted) (2020): pp. XXX-XXX. [link]
• Yücel, F., Habicht, F., Bohon, M.D., Paschereit, "Autoignition in stratified mixtures for pressure gain combustion," Proceedings of the Combustion Institute (Accepted) (2020): pp. XXX-XXX. [link]

NO_X

• Bohon, M.D., Guiberti, T.F., Roberts, W.L., "PLIF measurements of non-thermal NO concentrations in alcohol and alkane premixed flames," Combustion and Flame 194 (2018): pp. 363-375. [link]
• Bohon, M.D., Guiberti, T.F., Sarathy, S.M., Roberts, W.L., "Variations in non-thermal NO formation pathways in alcohol flames," Proceedings of the Combustion Institute 36 (2017): pp. 3995-4002. [link]
• Bohon, M.D., Al Rashidi, M.J., Sarathy, S.M., Roberts, W.L., "Experiments and simulations of NOx formation in the combustion of hydroxylated fuels," Combustion and Flame 162 (2015): pp. 2322-2336. [link]
• Bohon, M.D., Roberts, W.L., "NOx emissions from high swirl turbulent spray flames with highly oxygenated fuels," Proceedings of the Combustion Institute 34 (2013): pp. 1705-1712. [link]
• Bohon, M.D., Metzger, B.A., Linak, W.P., King, C.J., Roberts, W.L., "Glycerol combustion and emissions," Proceedings of the Combustion Institute 33 (2011): pp. 2717-2724. [link]