| 273 - 291 |
Numerical evaluation of equivalence ratio measurement using OH* and CH* chemiluminescence in premixed and non-premixed methane-air flames
Panoutsos CS, Hardalupas Y, Taylor AMKP |
| 292 - 301 |
Laminar burning velocities at high pressure for primary reference fuels and gasoline: Experimental and numerical investigation
Jerzembeck S, Peters N, Pepiot-Desjardins P, Pitsch H |
| 302 - 309 |
Enhanced reactivity of nano-B/Al/CuO MIC's
Sullivan K, Young G, Zachariah MR |
| 310 - 321 |
Premixed flames in stagnating turbulence Part VI. Predicting the mean density and the permitted rates of strain for impinging reactant streams
Bray K, Champion M, Libby PA |
| 322 - 333 |
Combustion characteristics of boron nanoparticles
Young G, Sullivan K, Zachariah MR, Yu K |
| 334 - 347 |
Flamelet mathematical models for non-premixed laminar combustion
Carbonell D, Perez-Segarra CD, Coelho PJ, Oliva A |
| 348 - 361 |
Chemiluminescence of BO2 to map the creation of thermal NO in flames
Maligne D, Cessou A, Stepowski D |
| 362 - 373 |
Effects of CO addition on the characteristics of laminar premixed CH4/air opposed-jet flames
Wu CY, Chao YC, Cheng TS, Chen CP, Ho CT |
| 374 - 384 |
Investigations on the self-excited oscillations in a kerosene spray flame
Garcia MD, Mastorakos E, Dowling AP |
| 385 - 395 |
Large eddy simulation of soot formation in a turbulent non-premixed jet flame
El-Asrag H, Menon S |
| 396 - 404 |
Autoignited laminar lifted flames of propane in coflow jets with tribrachial edge and mild combustion
Choi BC, Kim KN, Chung SH |
| 405 - 416 |
Visualization of the unburned gas flow field ahead of an accelerating flame in an obstructed square channel
Johansen CT, Ciccarelli G |
| 417 - 428 |
Reduction of very large reaction mechanisms using methods based on simulation error minimization
Nagy T, Turanyi T |
| 429 - 438 |
Operational characteristics of a parallel jet MILD combustion burner system
Szego GG, Dally BB, Nathan GJ |
| 439 - 446 |
Effects of position and frequency of obstacles on turbulent premixed propagating flames
Hall R, Masri AR, Yaroshchyk R, Ibrahim SS |
| 447 - 459 |
Hysteresis and transition in swirling nonpremixed flames
Tummers MJ, Hubner AW, van Veen EH, Hanjalic K, van der Meer TH |
| 460 - 466 |
Characteristics of liquid ethanol diffusion flames from mini tube nozzles
Chen J, Peng XF, Yang ZL, Cheng J |
| 467 - 476 |
Mixture fraction analysis of combustion products in the upper layer of reduced-scale compartment fires
Ko GH, Hamins A, Bundy M, Johnsson EL, Kim SC, Lenhert DB |
| 477 - 483 |
A numerical study on the effect of hydrogen/reformate gas addition on flame temperature and NO formation in strained methane/air diffusion flames
Guo HS, Neill WS |
| 484 - 493 |
Effects of fuel type and equivalence ratios on the flickering of triple flames
Sahu KB, Kundu A, Ganguly R, Datta A |
| 494 - 504 |
The combustion chemistry of a fuel tracer: Measured flame speeds and ignition delays and a detailed chemical kinetic model for the oxidation of acetone
Pichon S, Black G, Chaumeix N, Yahyaoui M, Simmie JM, Curran HJ, Donohue R |
| 505 - 521 |
Modeling of autoignition and NO sensitization for the oxidation of IC engine surrogate fuels
Anderlohr JM, Bounaceur R, Da Cruz AP, Battin-Leclerc F |
| 522 - 530 |
An embedded upward flame spread model using 2D direct numerical simulations
Xie W, DesJardin PE |
| 531 - 538 |
An elementary model for the transition from conductive to penetrative burning in gas-permeable explosives
Kagan L, Sivashinsky G |
| 539 - 542 |
Effect of velocity inflow conditions on the stability of a CH4/air jet-flame
Troiani G |
| 543 - 546 |
Burn time of aluminum nanoparticles: Strong effect of the heating rate and melt-dispersion mechanism
Levitas VI |
