Fokion N. Egolfopoulos
Affiliations: | 1991- | Mechanical Engineering | University of Southern California, Los Angeles, CA, United States |
Area:
Engineering, energy, combustion, propulsionWebsite:
https://viterbi.usc.edu/directory/faculty/Egolfopoulos/FokionGoogle:
"Fokion N. Egolfopoulos"Bio:
http://poli.usc.edu/~fokionegolfopoulos/CFRL_USC_Website/F.N._Egolfopoulos_Homepage.html
https://orcid.org/0000-0002-7115-5304
https://scholar.google.com/citations?user=Nny3YfkAAAAJ&hl=en
https://www.proquest.com/openview/a731c82e848e1b050c26659c53103ffe/1
https://books.google.com/books?id=4_Xweh0WU4cC
Parents
Sign in to add mentor| Chung K. Law | grad student | 1985-1991 | Princeton (Fluid Dynamics and Combustion Tree) |
Children
Sign in to add trainee| Mustafa G. Andac | grad student | 2002 | USC |
| Jyh-Yih Ren | grad student | 2002 | USC |
| Adam T. Holley | grad student | 2008 | USC |
| Chunsheng Ji | grad student | 2011 | USC |
| Peter S. Veloo | grad student | 2011 | USC |
| Mir A. Jalali | grad student | 2013 | USC |
| Okjoo Park | grad student | 2013 | USC |
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Publications
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| Wang Y, Movaghar A, Wang Z, et al. (2020) Laminar flame speeds of methane/air mixtures at engine conditions: Performance of different kinetic models and power-law correlations Combustion and Flame. 218: 101-108 |
| Movaghar A, Lawson R, Egolfopoulos FN. (2020) Confined spherically expanding flame method for measuring laminar flame speeds: Revisiting the assumptions and application to C1C4 hydrocarbon flames Combustion and Flame. 212: 79-92 |
| Paxton L, Smolke J, Egolfopoulos FN. (2019) Effects of heat release and fuel type on highly turbulent premixed jet flames Proceedings of the Combustion Institute. 37: 2565-2572 |
| Long AE, Burbano H, Speth RL, et al. (2019) An apparatus-independent extinction strain rate in counterflow flames Proceedings of the Combustion Institute. 37: 1979-1987 |
| Jayachandran J, Egolfopoulos FN. (2019) Effect of unsteady pressure rise on flame propagation and near-cold-wall ignition Proceedings of the Combustion Institute. 37: 1639-1646 |
| Ansari A, Jayachandran J, Egolfopoulos FN. (2019) Parameters influencing the burning rate of laminar flames propagating into a reacting mixture Proceedings of the Combustion Institute. 37: 1513-1520 |
| Paxton L, Giusti A, Mastorakos E, et al. (2019) Assessment of experimental observables for local extinction through unsteady laminar flame calculations Combustion and Flame. 207: 196-204 |
| Souflas K, Psarakis EZ, Koutmos P, et al. (2018) Low Cost Image Processing of Bunsen Flame Photography for Estimation of Flame Speeds Combustion Science and Technology. 191: 1123-1138 |
| Tao Y, Xu R, Wang K, et al. (2018) A Physics-based approach to modeling real-fuel combustion chemistry – III. Reaction kinetic model of JP10 Combustion and Flame. 198: 466-476 |
| Wang K, Xu R, Parise T, et al. (2018) A physics-based approach to modeling real-fuel combustion chemistry – IV. HyChem modeling of combustion kinetics of a bio-derived jet fuel and its blends with a conventional Jet A Combustion and Flame. 198: 477-489 |