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Combustion Theory and Modelling Volume 5, 2001 - Issue 4
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Original Articles

Physical and numerical realizability requirements for flame surface density approaches

E R HawkesCambridge University Engineering Department, CFD Laboratory, Trumpington Street, Cambridge, CB2 1PZ, UK
&
R S CantCambridge University Engineering Department, CFD Laboratory, Trumpington Street, Cambridge, CB2 1PZ, UK
Pages 699-720 | Received 18 Jan 2000, Published online: 15 May 2007

Citations (34)

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Felix B. Keil, Nilanjan Chakraborty & Markus Klein. (2020) Flame Surface Density Transport Statistics for High Pressure Turbulent Premixed Bunsen Flames in the Context of Large Eddy Simulation. Combustion Science and Technology 192:11, pages 2070-2092.
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Vassilios Papapostolou, Nilanjan Chakraborty, Markus Klein & Hong G. Im. (2019) Effects of Reaction Progress Variable Definition on the Flame Surface Density Transport Statistics and Closure for Different Combustion Regimes. Combustion Science and Technology 191:8, pages 1276-1293.
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Chin Yik Lee & Stewart Cant. (2017) Large-eddy simulation of a bluff-body stabilised turbulent premixed flame using the transported flame surface density approach. Combustion Theory and Modelling 21:4, pages 722-748.
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Mohit Katragadda, Yuan Gao & Nilanjan Chakraborty. (2014) Modeling of the Strain Rate Contribution to the Flame Surface Density Transport for Non-Unity Lewis Number Flames in Large Eddy Simulations. Combustion Science and Technology 186:10-11, pages 1338-1369.
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T. Ma, O.T. Stein, N. Chakraborty & A.M. Kempf. (2014) A posteriori testing of the flame surface density transport equation for LES. Combustion Theory and Modelling 18:1, pages 32-64.
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M. Düsing, A. Sadiki & J. Janicka. (2006) Towards a classification of models for the numerical simulation of premixed combustion based on a generalized regime diagram. Combustion Theory and Modelling 10:1, pages 105-132.
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Articles from other publishers (28)

Tianyi Ma. (2023) Applications of Large-eddy Simulation Method for Flow Prediction of Internal Combustion Engines. Highlights in Science, Engineering and Technology 37, pages 228-237.
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Takashi Ohta, Yuta Onishi & Yasuyuki Sakai. (2022) Modulation of wall turbulence by propagating flame of premixed hydrogen–air combustion. Combustion and Flame 241, pages 112132.
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B. Wang, M. J. Cleary & A. R. Masri. (2021) Modeling of interfacial flows based on an explicit volume diffusion concept. Physics of Fluids 33:6.
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Abdellatif M. Sadeq, Samer F. Ahmed & Ahmad K. Sleiti. (2021) Transient 3D simulations of turbulent premixed flames of gas-to-liquid (GTL) fuel in a fan-stirred combustion vessel. Fuel 291, pages 120184.
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Peipei Zhao, Lipo Wang & Nilanjan Chakraborty. (2019) Vectorial structure of the near-wall premixed flame. Physical Review Fluids 4:6.
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Peipei Zhao, Lipo Wang & Nilanjan Chakraborty. (2018) Analysis of the flame–wall interaction in premixed turbulent combustion. Journal of Fluid Mechanics 848, pages 193-218.
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Chin Yik Lee & Stewart Cant. (2017) LES of Nonlinear Saturation in Forced Turbulent Premixed Flames. Flow, Turbulence and Combustion 99:2, pages 461-486.
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Konstantina Vogiatzaki. 2017. Encyclopedia of Maritime and Offshore Engineering. Encyclopedia of Maritime and Offshore Engineering 1 11 .
Joseph C. Oefelein. (2015) Advances in the Simulation of Turbulent Combustion. Advances in the Simulation of Turbulent Combustion.
Nilanjan Chakraborty & R.S. Cant. (2013) Turbulent Reynolds number dependence of flame surface density transport in the context of Reynolds averaged Navier–Stokes simulations. Proceedings of the Combustion Institute 34:1, pages 1347-1356.
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Sean P. Malkeson & Nilanjan Chakraborty. (2012) Statistical Analysis and a-priori Modelling of Flame Surface Density Transport in Turbulent Stratified Flames: A Direct Numerical Simulation Study. Flow, Turbulence and Combustion 90:1, pages 143-187.
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Evatt R. Hawkes, Obulesu Chatakonda, Hemanth Kolla, Alan R. Kerstein & Jacqueline H. Chen. (2012) A petascale direct numerical simulation study of the modelling of flame wrinkling for large-eddy simulations in intense turbulence. Combustion and Flame 159:8, pages 2690-2703.
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Mohit Katragadda & Nilanjan Chakraborty. (2012) Modelling of the Curvature Term of the Flame Surface Density Transport Equation for Large Eddy Simulations. Journal of Combustion 2012, pages 1-12.
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Mohit Katragadda & Nilanjan Chakraborty. (2012) A Priori Direct Numerical Simulation Modelling of the Curvature Term of the Flame Surface Density Transport Equation for Nonunity Lewis Number Flames in the Context of Large Eddy Simulations . International Journal of Chemical Engineering 2012, pages 1-14.
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Nilanjan Chakraborty & R.S. Cant. (2011) Effects of Lewis number on flame surface density transport in turbulent premixed combustion. Combustion and Flame 158:9, pages 1768-1787.
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Nilanjan Chakraborty & Evatt R. Hawkes. (2011) Determination of 3D flame surface density variables from 2D measurements: Validation using direct numerical simulation. Physics of Fluids 23:6.
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Jacqueline H. Chen. (2011) Petascale direct numerical simulation of turbulent combustion—fundamental insights towards predictive models. Proceedings of the Combustion Institute 33:1, pages 99-123.
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Evatt R. Hawkes, Ramanan Sankaran & Jacqueline H. Chen. (2011) Estimates of the three-dimensional flame surface density and every term in its transport equation from two-dimensional measurements. Proceedings of the Combustion Institute 33:1, pages 1447-1454.
Crossref
Stewart Cant. 2011. Turbulent Combustion Modeling. Turbulent Combustion Modeling 63 90 .
A. GRUBER, R. SANKARAN, E. R. HAWKES & J. H. CHEN. (2010) Turbulent flame–wall interaction: a direct numerical simulation study. Journal of Fluid Mechanics 658, pages 5-32.
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Adam M. Steinberg & James F. Driscoll. (2010) Stretch-rate relationships for turbulent premixed combustion LES subgrid models measured using temporally resolved diagnostics. Combustion and Flame 157:7, pages 1422-1435.
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B. Fiorina, R. Vicquelin, P. Auzillon, N. Darabiha, O. Gicquel & D. Veynante. (2010) A filtered tabulated chemistry model for LES of premixed combustion. Combustion and Flame 157:3, pages 465-475.
Crossref
Nilanjan Chakraborty & R.S. Cant. (2009) Direct Numerical Simulation analysis of the Flame Surface Density transport equation in the context of Large Eddy Simulation. Proceedings of the Combustion Institute 32:1, pages 1445-1453.
Crossref
N. Chakraborty, J. W. Rogerson & N. Swaminathan. (2008) A priori assessment of closures for scalar dissipation rate transport in turbulent premixed flames using direct numerical simulation . Physics of Fluids 20:4.
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Nilanjan Chakraborty & R. S. Cant. (2007) A priori analysis of the curvature and propagation terms of the flame surface density transport equation for large eddy simulation . Physics of Fluids 19:10.
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Heinz Pitsch. (2006) LARGE-EDDY SIMULATION OF TURBULENT COMBUSTION. Annual Review of Fluid Mechanics 38:1, pages 453-482.
Crossref
Joseph C. Oefelein. (2006) Large eddy simulation of turbulent combustion processes in propulsion and power systems. Progress in Aerospace Sciences 42:1, pages 2-37.
Crossref
C. K. Chan & Xiang-Gui Li. (2005) Flame Surface Density in Turbulent Premixed V-Flame with Buoyancy. Flow, Turbulence and Combustion 74:3, pages 273-289.
Crossref

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