1 |
On the flame structure and stabilization characteristics of autoignited laminar lifted n-heptane jet flames in heated coflow air Jung KS, Kim SO, Chung SH, Yoo CS Combustion and Flame, 223, 307, 2021 |
2 |
Stationary edge flames in a wedge with hydrodynamic variable-density interaction Shields B, Freund JB, Pantano C Combustion and Flame, 211, 347, 2020 |
3 |
Energy analysis of unsteady negative edge flames in a periodic flow Grib SW, Renfro MW Combustion and Flame, 215, 113, 2020 |
4 |
Assessment of the stabilization mechanisms of turbulent lifted jet flames at elevated pressure using combined 2-D diagnostics Guiberti TF, Boyette WR, Krishna Y, Roberts WL, Masri AR, Magnotti G Combustion and Flame, 214, 323, 2020 |
5 |
Edge flames in mixing layers: Effects of heat recirculation through thermally active splitter plates Lu ZB, Matalon M Combustion and Flame, 217, 262, 2020 |
6 |
Structures of laminar lifted flames in a non-premixed jet and their relationship with similarity solutions Hwang GJ, Kim NI Combustion and Flame, 219, 283, 2020 |
7 |
Effects of channel length on propagation behaviors of non-premixed H-2-air flames in Y-shaped micro combustors Xiang Y, Wang SX, Yuan ZL, Fan AW International Journal of Hydrogen Energy, 45(39), 20449, 2020 |
8 |
Direct numerical simulation on auto-ignition characteristics of turbulent supercritical hydrothermal flames Song CC, Luo K, Jin T, Wang H, Fan JR Combustion and Flame, 200, 354, 2019 |
9 |
A numerical investigation on the thermo-chemical structures of methane-oxygen diffusion flame-streets in a microchannel Kang X, Sun BW, Wang JY, Wang Y Combustion and Flame, 206, 266, 2019 |
10 |
Effects of Turbulence Intensity and Biogas Composition on the Localized Forced Ignition of Turbulent Mixing Layers d'Auzay CT, Papapostolou V, Ahmed SF, Chakraborty N Combustion Science and Technology, 191(5-6), 868, 2019 |