| 1 |
The Speed and Temperature of an Edge Flame Stabilized in a Mixing Layer: Dependence on Fuel Properties and Local Mixture Fraction Gradient
Lu ZB, Matalon M
Combustion Science and Technology, 192(7), 1274, 2020 |
| 2 |
Compressibility and heat release effects in high-speed reactive mixing layers I.: Growth rates and turbulence characteristics
Ferrer PJM, Lehnasch G, Mura A
Combustion and Flame, 180, 284, 2017 |
| 3 |
Compressibility and heat release effects in high-speed reactive mixing layers II. Structure of the stabilization zone and modeling issues relevant to turbulent combustion in supersonic flows
Ferrer PJM, Lehnasch G, Mura A
Combustion and Flame, 180, 304, 2017 |
| 4 |
Thermal auto-ignition in high-speed droplet-laden mixing layers
Ren ZX, Wang B, Xie QF, Wang DL
Fuel, 191, 176, 2017 |
| 5 |
A priori evaluation of subgrid-scale combustion models for diesel engine applications
Ameen MM, Abraham J
Fuel, 153, 612, 2015 |
| 6 |
Some numerical considerations in the simulation of low-Ma number hydrogen/air mixing layers
Owston R, Magi V, Abraham J
International Journal of Hydrogen Energy, 35(23), 12936, 2010 |
| 7 |
Direct numerical simulations of the double scalar mixing layer Part II: Reactive scalars
Mortensen M, Kops SMD, Cha CM
Combustion and Flame, 149(4), 392, 2007 |
| 8 |
Nanoparticle coagulation via a Navier-Stokes/nodal methodology: Evolution of the particle field
Garrick SC, Lehtinen KEJ, Zachariah MR
Journal of Aerosol Science, 37(5), 555, 2006 |
| 9 |
Particle dispersion in organized vortex structures within turbulent free shear flows
Yang X, Thomas NH, Guo LJ
Chemical Engineering Science, 55(7), 1305, 2000 |
| 10 |
Effect of dispersion characteristics on particle temperature in an idealized nonpremixed reacting jet
Glaze DJ, Frankel SH
International Journal of Multiphase Flow, 26(4), 609, 2000 |
