| 1 - 14 |
An evaluation of flame surface density models for turbulent premixed jet flames
Prasad ROS, Gore JP |
| 15 - 47 |
The mechanism of two-dimensional pocket formation in lean premixed methane-air flames with implications to turbulent combustion
Chen JH, Echekki T |
| 49 - 61 |
Measurements of soot production and thermal radiation from confined turbulent jet diffusion flames of methane
Brookes SJ, Moss JB |
| 62 - 83 |
Large molecules, radicals, ions, and small soot particles in fuel-rich hydrocarbon flames - Part I: Positive ions of polycyclic aromatic hydrocarbons (PAH) in low-pressure premixed flames of acetylene and oxygen
Weilmunster P, Keller A, Homann KH |
| 84 - 93 |
Scaling laws of turbulent ceiling fires
Arpaci VS, Agarwal A |
| 94 - 104 |
Heat capacity and thermal conductivity considerations for coal particles during the early stages of rapid heating
Maloney DJ, Sampath R, Zondlo JW |
| 105 - 119 |
Measurement of mass transfer between the bubble and dense phases in a fluidized bed combustor
Campos JBLM, Mota ODS, Pinto AMFR |
| 120 - 135 |
An application of ultrasonic tomographic imaging to study smoldering combustion
Tse SD, Anthenien RA, Fernandez-Pello AC |
| 136 - 153 |
Highly strained turbulent rich methane flames stabilized by hot combustion products
Mansour MS, Chen YC, Peters N |
| 154 - 165 |
Formation and evolution of two-dimensional cellular detonations
Gamezo VN, Desbordes D |
| 166 - 176 |
Inhibition of nonpremixed flames by phosphorus-containing compounds
MacDonald MA, Jayaweera TM, Fisher EM, Gouldin FC |
| 177 - 191 |
Combustion and heat transfer in model two-dimensional porous burners
Hackert CL, Ellzey JL, Ezekoye OA |
| 192 - 206 |
Experimental and numerical studies of a triple flame
Kioni PN, Bray KNC, Greenhalgh DA, Rogg B |
| 207 - 219 |
Numerical study of the inhibition of premixed and diffusion flames by iron pentacarbonyl
Rumminger MD, Reinelt D, Babushok V, Linteris GT |
| 220 - 232 |
Measurements of conditional velocities in turbulent premixed flames by simultaneous OH PLIF and PTV
Frank JH, Kalt PAM, Bilger RW |
| 233 - 242 |
Morphology of chromium emissions from a laminar hydrogen diffusion flame
Kennedy IM, Zhang Y, Jones AD, Chang DPY, Kelly PB, Yoon Y |
| 243 - 258 |
Two-dimensional modelling for catalytically stabilized combustion of a lean methane-air mixture with elementary homogeneous and heterogeneous chemical reactions
Dogwiler U, Benz P, Mantzaras J |
| 259 - 271 |
Flame dynamics in a vented vessel connected to a duct: 1. Mechanism of vessel-duct interaction
Ponizy B, Leyer JC |
| 272 - 281 |
Flame dynamics in a vented vessel connected to a duct: 2. Influence of ignition site, membrane rupture, and turbulence
Ponizy B, Leyer JC |
| 282 - 290 |
Laser-saturated fluorescence measurements of nitric oxide in an inverse diffusion flame
Partridge WP, Reisel JR, Laurendeau NM |
| 291 - 296 |
Can soot primary particle size be determined using laser-induced incandescence?
Vander Wal RL, Ticich TM, Stephens AB |
| 297 - 301 |
Classification of combustion regimes in a packed bed of particles based on the relevant time and length scales
Peters B |
| 302 - 306 |
An analytical solution for the quasi-steady droplet combustion
Fachini F |
| 307 - 309 |
Gas chromatography as a complementary analytical technique to molecular beam mass spectrometry for studying flame structure
Ancia R, Van Tiggelen PJ, Vandooren J |
| 310 - 312 |
Comment on "Approximations for burning velocities and Markstein numbers for lean hydrocarbon and methanol flames," by U. C. Muller, M. Bollig, and N. Peters
Kwon OC, Aung KT, Tseng LK, Ismail MA, Faeth GM |
