| 1 - 12 |
A modified CCW theory for detonation waves
Li H, Ben-Dor G |
| 13 - 26 |
Control of NOx emissions in confined flames by oscillations
Poppe C, Sivasegaram S, Whitelaw JH |
| 27 - 37 |
The solubility of oxygen in liquid iron oxide during the combustion of iron rods in high-pressure oxygen
Steinberg TA, Kurtz J, Wilson DB |
| 38 - 52 |
Modelling the temporal evolution of a reduced combustion chemical system with an artificial neural network
Blasco JA, Fueyo N, Dopazo C, Ballester J |
| 53 - 65 |
Numerical study of unsteady turbulent premixed combustion: Application to flashback simulation
Thibaut D, Candel S |
| 66 - 78 |
Nitric oxide emissions from laminar diffusion flames: Effects of air-side versus fuel-side diluent addition
Feese JJ, Turns SR |
| 79 - 91 |
A model for calculating heat release in premixed turbulent flames
Schmid HP, Habisreuther P, Leuckel W |
| 92 - 105 |
Counterflow spray combustion modeling with detailed transport and detailed chemistry
Gutheil E, Sirignano WA |
| 106 - 118 |
An induction parameter model for shock-induced hydrogen combustion simulations
Clifford LJ, Milne AM, Turanyi T, Boulton D |
| 119 - 134 |
Optimization of rate coefficients for simplified reaction mechanisms with genetic algorithms
Polifke W, Geng WQ, Dobbeling K |
| 135 - 146 |
Stochastic modeling of CO and NO in premixed methane combustion
Cannon SM, Brewster BS, Smoot LD |
| 147 - 163 |
A numerical study of a two-dimensional H-2-O-2-Ar detonation using a detailed chemical reaction model
Oran ES, Weber JW, Stefaniw EI, Lefebvre MH, Anderson JD |
| 164 - 180 |
Inhibition of premixed methane-air flames by fluoroethanes and fluoropropanes
Linteris GT, Burgess DR, Babushok V, Zachariah M, Tsang W, Westmoreland P |
| 181 - 197 |
A kinetic model of carbon burnout in pulverized coal combustion
Hurt R, Sun JK, Lunden M |
| 198 - 211 |
Finite rate chemistry and NO mole fraction in non-premixed turbulent flames
Neuber A, Krieger G, Tacke M, Hassel E, Janicka J |
| 212 - 223 |
Accounting for reactant consumption in the thermal explosion problem - III. Criticality conditions for the Arrhenius problem
Shouman AR, El-Sayed SA |
| 224 - 235 |
The normal detonation shock velocity curvature relationship for materials with nonideal equation of state and multiple turning points
Stewart DS, Yao J |
| 236 - 241 |
Laser-induced fluorescence of CF2 from a CH4 flame and an H-2 flame with addition of HCFC-22 and HFC-134a
Su Y, Gu YW, Reck GP, Rothe EW, Francisco JS |
| 242 - 248 |
An experimental determination of the laminar burning velocities and extinction stretch rates of benzene/air flames
Wang CH, Ueng GJ, Tsay MS |
| 249 - 257 |
Emissions reduction and pyrolysis gas destruction in an acoustically driven dump combustor
Pont G, Cadou CP, Karagozian AR, Smith OI |
| 258 - 263 |
Combustion rate of burning graphite in a stagnation flow of water vapor
Makino A, Fujizaki H, Araki N |
| 264 - 270 |
Soot formation in counterflow ethylene diffusion flames from 1 to 2.5 atmospheres
Du DX, Wang H, Law CK |
| 271 - 273 |
On droplet enhancement of the burning velocity of laminar premixed spray flames
Greenberg JB, Silverman I, Tambour Y |
| 274 - 276 |
The contribution to char burnout from gasification by H2O and CO2 during pulverized-coal flame combustion
Stanmore BR, Visona SP |
