| 1 |
A priori evaluation of the Double-conditioned Conditional Source-term Estimation model for high-pressure heptane turbulent combustion using DNS data obtained with one-step chemistry
Bushe WK, Devaud C, Bellan J
Combustion and Flame, 217, 131, 2020 |
| 2 |
The uniform conditional state model for turbulent reacting flows
Hendra GR, Bushe WK
Combustion and Flame, 205, 484, 2019 |
| 3 |
The modeling of the turbulent reaction rate under high-pressure conditions: A priori evaluation of the Conditional Source-term Estimation concept
Devaud C, Bushe WK, Bellan J
Combustion and Flame, 207, 205, 2019 |
| 4 |
Spatial gradients of conditional averages in turbulent flames
Bushe WK
Combustion and Flame, 192, 314, 2018 |
| 5 |
Direct comparison of PDF and scalar dissipation rates between LEM simulations and experiments for turbulent, premixed methane air flames
Tsui HP, Kamal MM, Hochgreb S, Bushe WK
Combustion and Flame, 165, 208, 2016 |
| 6 |
Direct numerical simulation and reaction rate modelling of premixed turbulent flames
Luo K, Wang HO, Bushe WK, Fan JR
International Journal of Hydrogen Energy, 39(23), 12158, 2014 |
| 7 |
Effects of Hydrogen Addition on High-Pressure Nonpremixed Natural Gas Combustion
Wu N, McTaggart-Cowan GP, Bushe WK, Davy MH
Combustion Science and Technology, 183(1), 20, 2011 |
| 8 |
The influence of fuel composition on a heavy-duty, natural-gas direct-injection engine
McTaggart-Cowan GP, Rogak SN, Munshi SR, Hill PG, Bushe WK
Fuel, 89(3), 752, 2010 |
| 9 |
EFFECTS OF FUEL COMPOSITION ON HIGH-PRESSURE NON-PREMIXED NATURAL GAS COMBUSTION
McTaggart-Cowan GP, Wu N, Jin B, Rogak SN, Davy MH, Bushe WK
Combustion Science and Technology, 181(3), 397, 2009 |
| 10 |
Experimental and kinetic study of autoignition in methane/etliane/air and methane/propane/air mixtures under engine-relevant conditions
Huang J, Bushe WK
Combustion and Flame, 144(1-2), 74, 2006 |
