| 285 - 293 |
Experiments and numerical simulation on the laminar flame speeds of dichloromethane and trichloromethane
Leylegian JC, Zhu DL, Law CK, Wang H |
| 294 - 302 |
Mass-spectrometric sampling of ions from flames at atmospheric pressure: The effects of applied electric fields and the variation of electric potential in a flame
Axford SDT, Goodings JM, Hayhurst AN |
| 303 - 318 |
Appearance and stability of a laminar conical premixed flame subjected to an acoustic perturbation
Bourehla A, Baillot F |
| 319 - 335 |
A turbulent jet chemical reaction model: NOx production in jet flames
Broadwell JE, Lutz AE |
| 336 - 348 |
Development of a coherent flamelet model for a spark-ignited turbulent premixed flame in a closed vessel
Choi CR, Huh KY |
| 349 - 358 |
Transient heating, gasification, and oxidation of an energetic liquid fuel
Schiller D, Li J, Sirignano WA |
| 359 - 369 |
Pyrometric determination of temperature in rich flames and wavelength dependence of their emissivity
Block B, Hentschel W, Ertmer W |
| 370 - 380 |
Synergistic effect of ethylene-propane mixture on soot formation in laminar diffusion flames
Hwang JY, Lee W, Kang HG, Chung SH |
| 381 - 396 |
The strong-jet/weak-jet problem and aerodynamic modeling of the CGRI burner
Grandmaison EW, Yimer I, Becker HA, Sobiesiak A |
| 397 - 419 |
Numerical simulation of premixed combustion processes in closed tubes
Bielert U, Sichel M |
| 420 - 435 |
Numerical modeling of NO formation in laminar Bunsen flames - A flamelet approach
Chou CP, Chen JY, Yam CG, Marx KD |
| 436 - 456 |
Ignition in nonpremixed counterflowing hydrogen versus heated air: Computational study with skeletal and reduced chemistry
Kreutz TG, Law CK |
| 457 - 468 |
Laminar burning velocities of trifluoromethane-methane mixtures: Experiment and numerical simulation
Saso Y, Zhu DL, Wang H, Law CK, Saito N |
| 469 - 483 |
Time resolved velocity and turbulence measurements in turbulent gaseous explosions
Lindstedt RP, Sakthitharan V |
| 484 - 501 |
Dynamic modeling of soot particle coagulation and aggregation: Implementation with the method of moments and application to high-pressure laminar premixed flames
Kazakov A, Frenklach M |
| 502 - 514 |
Collisional quenching of CH(A), OH(A), and NO(A) in low pressure hydrocarbon flames
Tamura M, Berg PA, Harrington JE, Luque J, Jeffries JB, Smith GP, Crosley DR |
| 515 - 530 |
CO2 laser-induced combustion of ammonium dinitramide (ADN)
Fetherolf BL, Litzinger TA |
| 531 - 545 |
Rapid compression machines: Heat transfer and suppression of corner vortex
Lee D, Hochgreb S |
| 546 - 555 |
Correlations for the laminar-burning velocity of methane/diluent/air mixtures obtained in free-fall experiments
Stone R, Clarke A, Beckwith P |
| 556 - 568 |
Steady deflagration of HMX with simple kinetics: A gas phase chain reaction model
Ward MJ, Son SF, Brewster MQ |
| 569 - 576 |
Thermal decomposition of energetic materials 72: Unusual behavior of substituted furazan compounds upon flash pyrolysis
Williams GK, Brill TB |
| 577 - 584 |
Revisited flamelet model for nonpremixed combustion in supersonic turbulent flows
Sabel'nikov V, Deshaies B, Da Silva LFF |
| 585 - 590 |
A burner-type trap for particulate matter from a diesel engine
Park DS, Kim JU, Kim ES |
| 591 - 593 |
Formation of twisted AB-graphitic and fullerene-related tubular structures during soot deposition from the flaming combustion of polymers
Dunne LJ, Nolan PF, Terrones M, Munn J, Jones A, Kathirgamanathan P, Fernandez J |
| 594 - 596 |
A ring stabilizer for lean premixed turbulent flames
Johnson MR, Kostiuk LW, Cheng RK |
