| 1 |
A direct numerical simulation of Jet A flame kernel quenching
Krisman A, Meagher P, Zhao XY, Park JW, Lu TF, Chen JH
Combustion and Flame, 225, 349, 2021 |
| 2 |
Assessing the impact of multicomponent diffusion in direct numerical simulations of premixed, high-Karlovitz, turbulent flames
Fillo AJ, Schlup J, Blanquart G, Niemeyer KE
Combustion and Flame, 223, 216, 2021 |
| 3 |
Data driven analysis and prediction of MILD combustion mode
Jigjid K, Tamaoki C, Minamoto Y, Nakazawa R, Inoue N, Tanahashi M
Combustion and Flame, 223, 474, 2021 |
| 4 |
Numerical investigations of strong hydrodynamic interaction between neighboring particles inertially driven in microfluidic flows
Udono H
Advanced Powder Technology, 31(9), 4107, 2020 |
| 5 |
Two-dimensional oscillatory motion of inertially focused particles in microfluidic flows
Udono H
Advanced Powder Technology, 31(8), 3447, 2020 |
| 6 |
CURVATURE-BASED INTERFACE RESOLUTION QUALITY (IRQ) INDICATOR TO ASSESS SIMULATION ACCURACY
Canu R, Duret B, Reveillon J, Demoulin FX
Atomization and Sprays, 30(1), 31, 2020 |
| 7 |
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 |
| 8 |
Prediction of ignition modes of NTC-fuel/air mixtures with temperature and concentration fluctuations
Luong MB, Perez FEH, Im HG
Combustion and Flame, 213, 382, 2020 |
| 9 |
DNS study of the global heat release rate during early flame kernel development under engine conditions
Falkenstein T, Kang S, Cai LM, Bode M, Pitsch H
Combustion and Flame, 213, 455, 2020 |
| 10 |
A DNS study of the impact of gravity on spherically expanding laminar premixed flames
Berger L, Hesse R, Kleinheinz K, Hegetschweiler MJ, Attili A, Beeckmann J, Linteris GT, Pitsch H
Combustion and Flame, 216, 412, 2020 |
