317 - 318 |
A perspective on the role of microgravity in combustion research Ronney PD |
319 - 320 |
NASA's Microgravity Combustion Research Program: Past and future Urban DL, King MK |
321 - 322 |
Combustion experiments on STS-83 and STS-94: The crew's perspective Linteris GT, Voss J, Crouch R |
323 - 333 |
Experimental study of aluminum particle flame evolution in normal and micro-gravity Dreizin EL |
334 - 347 |
Fuel preheat effects on soot-field structure in laminar gas jet diffusion flames burning in 0-g and 1-g Konsur B, Megaridis CM, Griffin DW |
348 - 359 |
Experimental and numerical study of flame ball IR and UV emissions Abid M, Wu MS, Liu JB, Ronney PD, Ueki M, Maruta K, Kobayasiii H, Niioka T, Vanzandt DM |
360 - 375 |
Effects of buoyancy on lean premixed v-flames - Part I: Laminar and turbulent flame structures Cheng RK, Bedat B |
376 - 386 |
Shapes of buoyant and nonbuoyant laminar jet diffusion flames Sunderland PB, Mendelson BJ, Yuan ZG, Urban DL |
387 - 397 |
Detailed numerical simulation of flame ball structure and dynamics Wu MS, Ronney PD, Colantonio RO, Vanzandt DM |
398 - 414 |
Space shuttle based microgravity smoldering combustion experiments Walther DC, Fernandez-Pello AC, Urban DL |
415 - 431 |
Shapes of nonbuoyant round luminous hydrocarbon/air laminar jet diffusion flames Lin KC, Faeth GM, Sunderland PB, Urban DL, Yuan ZG |
432 - 459 |
Numerical modeling of isolated n-alkane droplet flames: Initial comparisons with ground and space-based microgravity experiments Marchese AJ, Dryer FL, Nayagam V |