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Combustion Science and Technology Volume 57, 1988 - Issue 4-6
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Original Articles

An Asymptotic Analysis of Supersonic Reacting Mixing Layers

T. L. JACKSON Department of Mathematical Sciences, Old Dominion University, Norfolk, Virginia, 23529; Institute for Computer Applications in Science and Engineering, NASA Langley Research Center, Hampton, Virginia, 23665
&
M. Y. HUSSAINI Institute for Computer Applications in Science and Engineering, NASA Langley Research Center, Hampton, Virginia, 23665
Pages 129-140 | Received 24 Mar 1987, Published online: 27 Apr 2007

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Laurent Gomet, Vincent Robin & Arnaud Mura. (2012) Influence of Residence and Scalar Mixing Time Scales in Non-Premixed Combustion in Supersonic Turbulent Flows. Combustion Science and Technology 184:10-11, pages 1471-1501.
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Jean-François Izard, Guillaume Lehnasch & Arnaud Mura. (2009) A Lagrangian Model of Combustion in High-Speed Flows: Application to Scramjet Conditions. Combustion Science and Technology 181:11, pages 1372-1396.
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B. HAN, C.J. SUNG*M. NISHIOKA. (2004) EFFECTS OF VITIATED AIR ON HYDROGEN IGNITION IN A HIGH-SPEED LAMINAR MIXING LAYER. Combustion Science and Technology 176:3, pages 305-330.
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Y. JU. (1995) Asymptotic and Numerical Analyses of Ignition of a Fuel Jet in a Supersonic Airstream. Combustion Science and Technology 108:1-3, pages 47-65.
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Youngbin Yoon, Jeffrey M. Donbar & James F. Driscoll*. (1994) Blowout Stability Limits Of a Hydrogen Jet Flame In a Supersonic, Heated, Coflowinq Air Stream. Combustion Science and Technology 97:1-3, pages 137-156.
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DOMINIQUE THÉVENIN & SÉBASTIEN CANDEL. (1993) Effect of Variable Strain on the Dynamics of Diffusion Flame Ignition. Combustion Science and Technology 91:1-3, pages 73-94.
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LUIS FERNANDO FIGUEIRA DA SILVA, BRUNO DESHAIES, MICHEL CHAMPION & MICHEL RENE-CORAIL. (1993) Some Specific Aspects of Combustion in Supersonic H2-Air Laminar Mixing Layers. Combustion Science and Technology 89:5-6, pages 317-333.
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MICHÉLEG. MACARAEG, T. L. JACKSON & M. Y. HUSSAINI. (1993) Ignition and Structure of a Laminar Diffusion Flame in the Field of a Vortex. Combustion Science and Technology 87:1-6, pages 363-387.
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S. A. Gaponov, S. O. Morozov & A. N. Semenov. (2024) A laminar supersonic boundary layer under the conditions of diffusive hydrogen-air flame and its stability. Thermophysics and Aeromechanics 30:6, pages 1095-1110.
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Jieli Wei, Jian An, Nana Wang, Jian Zhang & Zhuyin Ren. (2023) Velocity nonuniformity and wall heat loss coupling effect on supersonic mixing layer flames. Aerospace Science and Technology 141, pages 108545.
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V. I. Lysenko, S. A. Gaponov, B. V. Smorodsky, A. N. Semenov, S. O. Morozov & A. V. Starov. (2023) Influence of distributed hydrogen injection and combustion on supersonic boundary layer stability and transition. Physics of Fluids 35:9.
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S. A. Gaponov. Boundary layer stability under conditions of a heat supply into its internal area. Boundary layer stability under conditions of a heat supply into its internal area.
Di Lu & Fang Chen. 2021. Proceedings of the International Conference on Aerospace System Science and Engineering 2020. Proceedings of the International Conference on Aerospace System Science and Engineering 2020 243 252 .
S. A. Gaponov. (2020) EFFECT OF HEAT SUPPLY TO A NARROW BAND OF THE BOUNDARY LAYER ON ITS STABILITY. Journal of Applied Mechanics and Technical Physics 61:5, pages 685-692.
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Cleopatra Cuciumita, Daniel Olaru, Marius Enache & Florin Florean. (2018) Experimental studies on injection nozzle flame stability for gas turbines using in-situ combustion applications. Transportation Research Procedia 29, pages 92-105.
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Pedro José Martínez Ferrer, Guillaume Lehnasch & Arnaud Mura. (2017) Compressibility and heat release effects in high-speed reactive mixing layers II. Structure of the stabilization zone and modeling issues relevant to turbulent combustion in supersonic flows. Combustion and Flame 180, pages 304-320.
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Obula Reddy Kummitha. (2017) Numerical analysis of passive techniques for optimizing the performance of scramjet combustor. International Journal of Hydrogen Energy 42:15, pages 10455-10465.
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César Huete, Antonio L. Sánchez & Forman A. Williams. (2017) Diffusion-Flame Ignition by Shock-Wave Impingement on a Hydrogen–Air Supersonic Mixing Layer. Journal of Propulsion and Power 33:1, pages 256-263.
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Cleopatra Florentina Cuciumita, Ionuţ Porumbel & Sterian Dănăilă. (2016) Gas Turbine Using<i> In Situ</i> Combustion. Applied Mechanics and Materials 859, pages 20-28.
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Antonio L. Sanchez, Cesar Huete & Forman Williams. (2016) Diffusion-Flame Ignition by Shock-Wave Impingement on a Hydrogen-Air Supersonic Mixing Layer. Diffusion-Flame Ignition by Shock-Wave Impingement on a Hydrogen-Air Supersonic Mixing Layer.
Chen Qian, Wang Bing, Zhang Huiqiang, Zhang Yunlong & Gao Wei. (2016) Numerical investigation of H 2 /air combustion instability driven by large scale vortex in supersonic mixing layers. International Journal of Hydrogen Energy 41:4, pages 3171-3184.
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César Huete, Antonio L. Sánchez, Forman A. Williams & Javier Urzay. (2015) Diffusion-flame ignition by shock-wave impingement on a supersonic mixing layer. Journal of Fluid Mechanics 784, pages 74-108.
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YunLong Zhang, Bing Wang & HuiQiang Zhang. (2014) Ignition, flame propagation and extinction in the supersonic mixing layer flow. Science China Technological Sciences 57:11, pages 2256-2264.
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W. A. Sirignano, D. Dunn-Rankin, F. Liu, B. Colcord & S. Puranam. (2012) Turbine Burners: Performance Improvement and Challenge of Flameholding. AIAA Journal 50:8, pages 1645-1669.
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Ben Colcord, William Sirignano & Feng Liu. (2012) Turbine-Burner Model: Cavity Flameholding in a Converging, Turning Channel Flow. Turbine-Burner Model: Cavity Flameholding in a Converging, Turning Channel Flow.
Yann Moule, Vladimir Sabel'nikov & Arnaud Mura. (2011) Modelling of Self-Ignition Processes in Supersonic Non Premixed Coflowing Jets Based on a PaSR Approach. Modelling of Self-Ignition Processes in Supersonic Non Premixed Coflowing Jets Based on a PaSR Approach.
Arnaud Mura & Jean-Francois Izard. (2010) Numerical Simulation of Supersonic Nonpremixed Turbulent Combustion in a Scramjet Combustor Model. Journal of Propulsion and Power 26:4, pages 858-868.
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William Sirignano, Derek Dunn-Rankin, Feng Liu, B Colcord & S Puranam. (2009) Turbine Burners: Flameholding in Accelerating Flow. Turbine Burners: Flameholding in Accelerating Flow.
A.T. Sriram, A.C. Zambon & H.K. Chelliah. (2008) Validation of Ethylene-Air Reduced Reaction Models in Supersonic Shear Flows. Validation of Ethylene-Air Reduced Reaction Models in Supersonic Shear Flows.
Yang Na, Seungbae Lee & Dongshin Shin. (2007) Laminar diffusion flame in the reacting mixing layer. Journal of Mechanical Science and Technology 21:2, pages 384-393.
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B. Han, C. Sung & M. Nishioka. (2002) Effects of vitiated air on hydrogen ignition in a supersonic laminar mixing layer. Effects of vitiated air on hydrogen ignition in a supersonic laminar mixing layer.
X. Fang, F. Liu & W. A. Sirignano. (2001) Ignition and Flame Studies for an Accelerating Transonic Mixing Layer. Journal of Propulsion and Power 17:5, pages 1058-1066.
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Carsten Mehring, Feng Liu & William Sirignano. (2001) Ignition and flame studies for a turbulent accelerating transonic mixing layer. Ignition and flame studies for a turbulent accelerating transonic mixing layer.
William A. Sirignano & Inchul Kim. (1997) Diffusion flame in a two-dimensional, accelerating mixing layer. Physics of Fluids 9:9, pages 2617-2630.
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Antonio L. Sánchez. (1997) Nonpremixed spontaneous ignition in the laminar wake of a splitter plate. Physics of Fluids 9:7, pages 2032-2044.
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M. Nishioka & C.K. Law. (1997) A numerical study of ignition in the supersonic hydrogen/air laminar mixing layer. Combustion and Flame 108:1-2, pages 199-219.
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B. Deshaies, L. F. Figueira Da Silva & M. René-Corail. 1997. IUTAM Symposium on Combustion in Supersonic Flows. IUTAM Symposium on Combustion in Supersonic Flows 15 42 .
James Driscoll, Hwanil Huh, Youngbin Yoon & Jeffrey Donbar. (1995) Measured properties of supersonic hydrogen-air jet flames. Measured properties of supersonic hydrogen-air jet flames.
T. Niioka, Y. Ju, T. Fujimori & K. Takita. 1995. Modeling in Combustion Science. Modeling in Combustion Science 337 351 .
Y. Ju & T. Niioka. (1994) Extinction of a diffusion flame in supersonic mixing layer. Combustion and Flame 97:3-4, pages 423-428.
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H. G. Im, B. H. Chao, J. K. Bechtold & C. K. Law. (1994) Analysis of thermal ignition in the supersonic mixing layer. AIAA Journal 32:2, pages 341-349.
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C. E. Grosch. 1994. Combustion in High-Speed Flows. Combustion in High-Speed Flows 131 190 .
Amable Liñán. 1994. Combustion in High-Speed Flows. Combustion in High-Speed Flows 461 476 .
Luis Fernando Figueira da Silva, Bruno Deshaies & Michel Champion. (1993) Numerical study of ignition within hydrogen-air supersonic boundary layers. AIAA Journal 31:5, pages 884-890.
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Y. Ju & T. Niioka. (1993) Ignition analysis of unpremixed reactants with chain mechanism in a supersonic mixing layer. AIAA Journal 31:5, pages 863-868.
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H. G. Im, J. K. Bechtold & C. K. Law. (2006) Analysis of thermal ignition in supersonic flat-plate boundary layers. Journal of Fluid Mechanics 249:-1, pages 99.
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H. IM, B. CHAO, J. BECHTOLD & C. LAW. (1993) Analysis of thermal ignition in a supersonic mixing layer. Analysis of thermal ignition in a supersonic mixing layer.
T. L. Jackson. 1992. Major Research Topics in Combustion. Major Research Topics in Combustion 131 161 .
C. E. Grosch & T. L. Jackson. (1991) Ignition and structure of a laminar diffusion flame in a compressible mixing layer with finite rate chemistry. Physics of Fluids A: Fluid Dynamics 3:12, pages 3087-3097.
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T. L. Jackson & C. E. Grosch. 1989. Numerical Combustion. Numerical Combustion 362 373 .

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