| 203 - 216 |
Laser-induced spark ignition of CH4/air mixtures
Phuoc TX, White FP |
| 217 - 232 |
Effects of stoichiometry on stretched premixed flames
Bechtold JK, Matalon M |
| 233 - 252 |
PDF modeling of lean premixed combustion using in situ tabulated chemistry
Cannon SM, Brewster BS, Smoot LD |
| 253 - 271 |
A flamelet description of premixed laminar flames and the relation with flame stretch
De Goey LPH, Boonkkamp JHMT |
| 272 - 290 |
Phase changes in boron ignition and combustion
Dreizin EL, Keil DG, Felder W, Vicenzi EP |
| 291 - 306 |
A study of the turbulent structure of a two-dimensional diffusion flame formed behind a slender bluff-body
Bakrozis AG, Papailiou DD, Koutmos P |
| 307 - 318 |
Modeling of NO formation in premixed, high-pressure methane flames
Thomsen DD, Kuligowski FF, Laurendeau NM |
| 319 - 334 |
The use of a closed-loop wind tunnel for measuring the combustion efficiency of flames in a cross flow
Bourguignon E, Johnson MR, Kostiuk LW |
| 335 - 345 |
Two-dimensional numerical modeling of a turbulent premixed flame stabilized in a stagnation flow
Karmed D, Champion M, Bruel P |
| 346 - 355 |
Effects of NO on the ignition of hydrogen and hydrocarbons by seated counterflowing air
Tan Y, Fotache CG, Law CK |
| 356 - 366 |
Control of soot emitted from acetylene diffusion flames by applying an electric field
Saito M, Arai T, Arai M |
| 367 - 373 |
A simplified, fundamentally based method for calculating NOx emissions in lean premixed combustors
Li SC, Williams FA, Gebert K |
