| 1 |
DNS-driven analysis of the Flamelet/Progress Variable model assumptions on soot inception, growth, and oxidation in turbulent flames
Wick A, Attili A, Bisetti F, Pitsch H
Combustion and Flame, 214, 437, 2020 |
| 2 |
A comprehensive study of flamelet tabulation methods for pulverized coal combustion in a turbulent mixing layer - Part I: A priori and budget analyses
Wen X, Rieth M, Scholtissek A, Stein OT, Wang HO, Luo K, Kempf AM, Kronenburg A, Fan J, Hasse C
Combustion and Flame, 216, 439, 2020 |
| 3 |
Large Eddy Simulation of medium-scale methanol pool fires - effects of pool boundary conditions
Ma L, Nmira F, Consalvi JL
Combustion and Flame, 222, 336, 2020 |
| 4 |
A computationally-efficient method for flamelet calculations
Lapointe S, Xuan Y, Kwon H, Whitesides RA, McNenly MJ
Combustion and Flame, 221, 94, 2020 |
| 5 |
On the application of dynamic zone flamelet model to large eddy simulation of supersonic hydrogen flame
Yao W
International Journal of Hydrogen Energy, 45(41), 21940, 2020 |
| 6 |
Analysis of pulverized coal flame stabilized in a 3D laminar counterflow
Wen X, Luo K, Wang HO, Luo YJ, Fan JR
Combustion and Flame, 189, 106, 2018 |
| 7 |
Assessment of differential diffusion effects in flamelet modeling of oxy-fuel flames
Gierth S, Hunger F, Popp S, Wu H, Ihme M, Hasse C
Combustion and Flame, 197, 134, 2018 |
| 8 |
A generalized flamelet tabulation method for partially premixed combustion
Wen X, Bai XS, Luo K, Wang H, Luo YJ, Fan JR
Combustion and Flame, 198, 54, 2018 |
| 9 |
Modelling heat loss effects in high temperature oxy-fuel flames with an efficient and robust non-premixed flamelet approach
Wollny P, Rogg B, Kempf A
Fuel, 216, 44, 2018 |
| 10 |
Prediction of hot coke oven gas reforming by LES coupled with the extended flamelet/progress variable approach
Yu PL, Norinaga K, Watanabe H, Kitagawa T
Fuel, 231, 234, 2018 |
