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Combustion Theory and Modelling Volume 12, 2008 - Issue 6
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Original Articles

Transported scalar PDF calculations of autoignition of a hydrogen jet in a heated turbulent co-flow

C.W. Lee Hopkinson Laboratory, Engineering Department, University of Cambridge, Trumpington Street, CB2 1PZ, UK
&
E. Mastorakos Hopkinson Laboratory, Engineering Department, University of Cambridge, Trumpington Street, CB2 1PZ, UK
Pages 1153-1178 | Received 12 Nov 2007, Accepted 13 Jun 2008, Published online: 15 Nov 2008

Citations (15)

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Read on this site (2)

Artur Tyliszczak, Agnieszka Wawrzak & Karol Wawrzak. (2023) Impact of a discretisation method and chemical kinetics on the accuracy of simulation of a lifted hydrogen flame. Combustion Theory and Modelling 27:2, pages 244-266.
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A. Fiolitakis & C. M. Arndt. (2020) Transported PDF simulation of auto-ignition of a turbulent methane jet in a hot, vitiated coflow. Combustion Theory and Modelling 24:2, pages 326-361.
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Articles from other publishers (13)

I. Stanković. (2018) Modelling of non-premixed turbulent combustion with Conditional Moment Closure (CMC)⋆. The European Physical Journal E 41:12.
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Agnieszka Rosiak & Artur Tyliszczak. (2016) LES-CMC simulations of a turbulent hydrogen jet in oxy-combustion regimes. International Journal of Hydrogen Energy 41:22, pages 9705-9717.
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Artur Tyliszczak. (2015) LES–CMC study of an excited hydrogen flame. Combustion and Flame 162:10, pages 3864-3883.
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Seyed Mohammad Mir Najafizadeh, Mohammad Taghi Sadeghi, Rahmat Sotudeh-Gharebagh & Dirk J.E.M. Roekaerts. (2013) Chemical structure of autoignition in a turbulent lifted H2/N2 jet flame issuing into a vitiated coflow. Combustion and Flame 160:12, pages 2928-2940.
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A. J. M. Buckrell & C. B. Devaud. (2013) Investigation of Mixing Models and Conditional Moment Closure Applied to Autoignition of Hydrogen Jets. Flow, Turbulence and Combustion 90:3, pages 621-644.
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I. Stanković, E. Mastorakos & B. Merci. (2013) LES-CMC Simulations of Different Auto-ignition Regimes of Hydrogen in a Hot Turbulent Air Co-flow. Flow, Turbulence and Combustion 90:3, pages 583-604.
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S.M. Mir Najafizadeh, M.T. Sadeghi & R. Sotudeh-Gharebagh. (2013) Analysis of autoignition of a turbulent lifted H2/N2 jet flame issuing into a vitiated coflow. International Journal of Hydrogen Energy 38:5, pages 2510-2522.
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Paul R. Medwell & Bassam B. Dally. (2012) Experimental Observation of Lifted Flames in a Heated and Diluted Coflow. Energy & Fuels 26:9, pages 5519-5527.
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Salvador Navarro-Martinez & Andreas Kronenburg. (2011) Flame Stabilization Mechanisms in Lifted Flames. Flow, Turbulence and Combustion 87:2-3, pages 377-406.
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Ivana Stanković, Antonios Triantafyllidis, Epaminondas Mastorakos, Chris Lacor & Bart Merci. (2010) Simulation of Hydrogen Auto-Ignition in a Turbulent Co-flow of Heated Air with LES and CMC Approach. Flow, Turbulence and Combustion 86:3-4, pages 689-710.
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Kamlesh G. Gupta & Tarek Echekki. (2011) One-dimensional turbulence model simulations of autoignition of hydrogen/carbon monoxide fuel mixtures in a turbulent jet. Combustion and Flame 158:2, pages 327-344.
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D.C. Haworth. (2010) Progress in probability density function methods for turbulent reacting flows. Progress in Energy and Combustion Science 36:2, pages 168-259.
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W. P. Jones & S. Navarro-Martinez. (2009) Numerical Study of n-Heptane Auto-ignition Using LES-PDF Methods. Flow, Turbulence and Combustion 83:3, pages 407-423.
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