| 1 - 1 |
Preface
Pitsch H, Williams FA |
| 2 - 15 |
Chemical kinetics of octane sensitivity in a spark-ignition engine
Westbrook CK, Mehl M, Pitz WJ, Sjoberg M |
| 16 - 26 |
Modeling the kinetics of the Shockless Explosion Combustion
Berndt P, Klein R |
| 27 - 33 |
A reduced reaction mechanism for the combustion of n-butane
Prince JC, Trevino C, Williams FA |
| 34 - 46 |
Consumption and hydrocarbon growth processes in a 2-methyl-2-butene flame
Ruwe L, Moshammer K, Hansen N, Kohse-Hoinghaus K |
| 47 - 59 |
Influence of the biofuel isomers diethyl ether and n-butanol on flame structure and pollutant formation in premixed n-butane flames
Tran LS, Pieper J, Zeng MR, Li YY, Zhang XY, Li W, Graf I, Qi F, Kohse-Hoinghaus K |
| 60 - 79 |
Automatic reduction and optimisation of chemistry for turbulent combustion modelling: Impact of the canonical problem
Jaouen N, Vervisch L, Domingo P, Ribert G |
| 80 - 90 |
Quasi-isobaric ignition near the flammability limits. Flame balls and self-extinguishing flames
Clavin P |
| 91 - 106 |
The large-activation-energy analysis of extinction of counterflow diffusion flames with non-unity Lewis numbers of the fuel
Linan A, Martinez-Ruiz D, Vera M, Sanchez AL |
| 107 - 117 |
Rate-ratio asymptotic analysis of the influence of addition of carbon monoxide on the structure and mechanisms of extinction of nonpremixed methane flames with comparison to experiments
Seshadri K, Bai XS |
| 118 - 122 |
Deflagrative, auto-ignitive, and detonative propagation regimes in engines
Bates L, Bradley D |
| 123 - 137 |
Abnormal combustion phenomena with different fuels in a spark ignition engine with direct fuel injection
Pischinger S, Gunther M, Budak O |
| 138 - 154 |
Scalar dissipation rate based multi-zone model for early-injected and conventional diesel engine combustion
Jochim B, Korkmaz M, Pitsch H |
| 155 - 169 |
The turbulent flame speed for low-to-moderate turbulence intensities: Hydrodynamic theory vs. experiments
Fogla N, Creta F, Matalon M |
| 170 - 179 |
Effect of unsteady stretching on the flame local dynamics
Zhang F, Zirwes T, Habisreuther P, Bockhorn H |
| 180 - 200 |
Effect of the mixing fields on the stability and structure of turbulent partially premixed flames in a concentric flow conical nozzle burner
Mansour MS, Elbaz AM, Roberts WL, Senosy MS, Zayed MF, Juddoo M, Masri AR |
| 201 - 219 |
LES combustion modeling using the Eulerian stochastic field method coupled with tabulated chemistry
Avdic A, Kuenne G, di Mare F, Janicka J |
| 220 - 236 |
Thin reaction zone and distributed reaction zone regimes in turbulent premixed methane/air flames: Scalar distributions and correlations
Zhou B, Brackmann C, Wang ZK, Li ZS, Richter M, Alden M, Bai XS |
| 237 - 242 |
Visualizing turbulent flames using flamelet libraries
Herrmann M |
| 243 - 258 |
In-situ tracking of mixture fraction gradient trajectories and unsteady flamelet analysis in turbulent non-premixed combustion
Scholtissek A, Dietzsch F, Gauding M, Hasse C |
| 259 - 269 |
Analysis of the filtered non-premixed turbulent flame
Wang LP |
| 270 - 282 |
Effects of hydrogen and nitrogen on soot volume fraction, primary particle diameter and temperature in laminar ethylene/air diffusion flames
Sun ZW, Dally B, Nathan G, Alwahabi Z |
| 283 - 291 |
A hysteresis phenomenon leading to spinning or standing azimuthal instabilities in an annular combustor
Prieur K, Durox D, Schuller T, Candel S |
| 292 - 306 |
Analysis of combustion noise of a turbulent premixed slot jet flame
Schlimpert S, Koh SR, Pausch K, Meinke M, Schroder W |
| 307 - 311 |
Transition to detonation of an expanding spherical flame
Kagan L, Sivashinsky G |
