| 1 |
Large-Eddy Simulation and analysis of a sooting lifted turbulent jet flame
Grader M, Eberle C, Gerlinger P
Combustion and Flame, 215, 458, 2020 |
| 2 |
Detailed modeling of a small-scale turbulent pool fire
Wu BF, Roy SP, Zhao XY
Combustion and Flame, 214, 224, 2020 |
| 3 |
Modelling soot formation in a benchmark ethylene stagnation flame with a new detailed population balance model
Hou DY, Lindberg CS, Manuputty MY, You XQ, Kraft M
Combustion and Flame, 203, 56, 2019 |
| 4 |
Influence of water-vapor in oxidizer stream on the sooting behavior for laminar coflow ethylene diffusion flames
Cepeda F, Jerez A, Demarco R, Liu FS, Fuentes A
Combustion and Flame, 210, 114, 2019 |
| 5 |
A post processing technique to predict primary particle size of sooting flames based on a chemical discrete sectional model: Application to diluted coflow flames
Bodor AL, Franzelli B, Faravelli T, Cuoci A
Combustion and Flame, 208, 122, 2019 |
| 6 |
Modeling soot particle size distribution in diesel engines
Duvvuri PP, Sukumaran S, Shrivastava RK, Sreedhara S
Fuel, 243, 70, 2019 |
| 7 |
Investigation on soot emissions from diesel-CNG dual-fuel
Zhou HQ, Li XR, Lee CFF
International Journal of Hydrogen Energy, 44(18), 9438, 2019 |
| 8 |
A numerical study of the effects of n-propylbenzene addition to n-dodecane on soot formation in a laminar coflow diffusion flame
Zhang TF, Thomson MJ
Combustion and Flame, 190, 416, 2018 |
| 9 |
Large eddy simulation of pressure and dilution-jet effects on soot formation in a model aircraft swirl combustor
Chong ST, Hassanaly M, Koo H, Mueller ME, Raman V, Geigle KP
Combustion and Flame, 192, 452, 2018 |
| 10 |
Application of the global soot model based on smoke point in simulation of multiple laminar diffusion flames
Niu Y, Zhang Y, Chen XF, Zhou DC
Combustion Science and Technology, 190(6), 1060, 2018 |
