| 1 - 16 |
Development of a two-part n-heptane oxidation mechanism for two stage combustion process in internal combustion engines
Maroteaux F |
| 17 - 31 |
Large eddy simulation of explosion deflagrating flames using a dynamic wrinkling formulation
Volpiani PS, Schmitt T, Vermorel O, Quillatre P, Veynante D |
| 32 - 44 |
Laser-diagnostic mapping of temperature and soot statistics in a 2-m diameter turbulent pool fire
Kearney SP, Grasser TW |
| 45 - 64 |
Uncertainty quantification of a newly optimized methanol and formaldehyde combustion mechanism
Olm C, Varga T, Valko E, Curran HJ, Turanyi T |
| 65 - 82 |
Turbulent jet ignition assisted combustion in a rapid compression machine
Validi A, Schock H, Jaberi F |
| 83 - 93 |
CSP-based chemical kinetics mechanisms simplification strategy for non-premixed combustion: An application to hybrid rocket propulsion
Ciottoli PP, Galassi RM, Lapenna PE, Leccese G, Bianchi D, Nasuti F, Greta F, Valorani M |
| 94 - 104 |
Impact of nitric oxide (NO) on n-heptane autoignition in a rapid compression machine
Chen ZY, Zhang P, Yang Y, Brear MJ, He X, Wang Z |
| 105 - 113 |
Experimental study and analysis on the interaction between two slot-burner buoyant turbulent diffusion flames at various burner pitches
Hu LH, Huang LL, Wang Q, Kuwana K |
| 114 - 128 |
Autoignition characteristics of oxygenated gasolines
Lee C, Ahmed A, Nasir EF, Badra J, Kalghatgi G, Sarathy SM, Curran H, Farooq A |
| 129 - 139 |
A new diagnostic for hydrocarbon fuels using 3.41-mu m diode laser absorption
Wang SK, Parise T, Johnson SE, Davidson DF, Hanson RK |
| 140 - 149 |
Direct estimation of edge flame speeds of lifted laminar jet flames and a modified stabilization mechanism
Jeon MK, Kim NI |
| 150 - 165 |
Simultaneous imaging of fuel, OH, and three component velocity fields in high pressure, liquid fueled, swirl stabilized flames at 5 kHz
Chterev I, Rock N, Ek H, Emerson B, Seitzman J, Jiang N, Roy S, Lee T, Gord J, Lieuwen T |
| 166 - 177 |
Approximate analytical solutions for temperature based transient mass flux and ignition time of a translucent solid at high radiant heat flux considering in-depth absorption
Gong JH, Li YB, Wang JH, Li J, Chen YX, Jiang JC, Wang ZR |
| 178 - 192 |
A comprehensive experimental and kinetic modeling study of n-propylbenzene combustion
Yuan WH, Li YY, Dagaut P, Wang YZ, Wang ZD, Qi F |
| 193 - 207 |
Lagrangian analysis of high-speed turbulent premixed reacting flows: Thermochemical trajectories in hydrogen-air flames
Hamlington PE, Darragh R, Briner CA, Towery CAZ, Taylor BD, Poludnenko AY |
| 208 - 210 |
Violation of collision limit in recently published reaction models
Chen DP, Wang K, Wang H |
| 211 - 219 |
The critical conditions for thermal explosion in a system heated at a constant rate
Sanchez-Rodriguez D, Farjas J, Roura P |
| 220 - 235 |
Flamelet regime characterization for non-premixed turbulent combustion simulations
Chan WL, Ihme M |
| 236 - 246 |
Ignition of a hydrogen-air mixture by low voltage electrical contact arcs
Shekhar R, Boeck LR, Uber C, Gerlach U |
| 247 - 262 |
Effects of the equivalence ratio on turbulent flame-shock interactions in a confined space
Wei HQ, Zhao JF, Zhou L, Gao DZ, Xu ZL |
| 263 - 276 |
Shock tube study and RRKM calculations on thermal decomposition of 2-chloroethyl methyl ether
Parandaman A, Rajakumar B |
| 277 - 298 |
An investigation of a turbulent spray flame using Large Eddy Simulation with a stochastic breakup model
Jones WP, Marquis AJ, Noh D |
| 299 - 310 |
Numerical analysis of laminar methane-air side-wall-quenching
Ganter S, Heinrich A, Meier T, Kuenne G, Jainski C, Rissmann MC, Dreizler A, Janicka J |
| 311 - 324 |
Raman/LIPF data of temperature and species concentrations in swirling hydrogen jet diffusion flames: Conditional analysis and comparison to laminar flamelets
Cheng TS, Chen JY, Pitz RW |
| 325 - 334 |
Measurement of the size distribution, volume fraction and optical properties of soot in an 80 kW propane flame
Backstrom D, Gunnarsson A, Gall D, Pei XY, Johansson R, Andersson K, Pathak RK, Pettersson JBC |
