displaying 3981 - 3990 results in total 4589
Kim, K. B.; Masiello, K. A.; Hahn, D. W.
view article (1.0)Reduction of Soot Emissions by Iron Pentacarbonly in Isooctane Diffusion Flames.Florida Univ., GainesvilleCombustion and Flame, Vol. 154, No. 1/2, 164-180, July 2008Kagan, L.; Sivashinsky, G.
view article (1.0)Autoignition Due to Hydraulic Resistance and Deflagration-to-Detonation Transition.Tel Aviv Univ., Tel Aviv 69978, IsraelCombustion and Flame, Vol. 154, No. 1/2, 186-190, July 2008Pepiot-Desjardins, P.; Pitsch, H.; Malhotra, R.; Kirby, S. R.; Boehman, A. L.
view article (1.0)Structural Group Analysis for Soot Reduction Tendency of Oxygenated Fuels.Stanford University, CA; SRI International, Menlo Park, CA; Pennsylvania State Univ., University ParkCombustion and Flame, Vol. 154, No. 1/2, 191-205, July 2008Bulut, L.; Yan, A.; Hurt, R. H.
view article (1.0)Catalytic Combustion as a Synthesis Tool for Micropatterned Carbon Materials.Brown Univ., Providence, RICombustion and Flame, Vol. 154, No. 1/2, 206-216, July 2008Dixon, M. J.; Schoegl, I.; Hull, C. B.; Ellzey, J. L.
view article (1.0)Experimental and Numerical Conversion of Liquid Heptane to Syngas Through Combustion in Porous Media.University of Texas, AustinCombustion and Flame, Vol. 154, No. 1/2, 217-231, July 2008Kim, S. K.; Kim, Y.
view article (1.0)Assessment of the Eulerian Particle Flamelet Model for Nonpremixed Turbulent Jet Flames.Korea Aerospace Research Institute, Daejeon 305-600, South Korea; Hanyang Univ., Seoul 133-701, South KoreaCombustion and Flame, Vol. 154, No. 1/2, 232-247, July 2008Yamada, H.; Suzaki, K.; Tezaki, A.; Goto, Y.
view article (1.0)Transition From Cool Flame to Thermal Flame in Compression Ignition Process.National Traffic Safety and Environment Laboratory, 7-42-27 Jindaiji-Higashimachi, Chofu, Tokyo 182-0012, Japan; Toyama Univ., Gofuku 3190, Toyama-shi, Toyama 930-8555, JapanCombustion and Flame, Vol. 154, No. 1/2, 248-258, July 2008Chakraborty, N.; Hawkes, E.R.; Chen, J. H.; Cant, R. S.
view article (1.0)Effects of Strain Rate and Curvature on Surface Density Function Transport in Turbulent Premixed Methane-Air and Hydrogen-Air Flames: A Comparative Study.Liverpool Univ., Brownlow Hill, Liverpool L69 3GH, UK; New South Wales Univ., Sydney, NSW 2052, Australia; Sandia National Laboratories, Livermore, CA; Cambridge Univ., Trumpington Street, Cambridge CB2 1PZ, UKCombustion and Flame, Vol. 154, No. 1/2, 259-280, July 2008Szego, G. G.; Dally, B. B.; Nathan, G. J.
view article (1.0)Scaling of NOx Emissions From a Laboratory-Scale Mild Combustion Furnace.Adelaide Univ., South Australia 5005, AustraliaCombustion and Flame, Vol. 154, No. 1/2, 281-295, July 2008Wangher, A.; Searby, G.; Quinard, J.
view article (1.0)Experimental Investigation of the Unsteady Response of Premixed Flame Fronts to Acoustic Pressure Waves.CNRS and Aix-Marseille Université, F-13384 Marseille cedex 13, FranceCombustion and Flame, Vol. 154, No. 1/2, 310-318, July 2008