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Combustion Theory and Modelling Volume 7, 2003 - Issue 2
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Original Articles

Flamelet modelling of non-premixed turbulent combustion with local extinction and re-ignition

Heinz Pitsch Center for Turbulence Research, Stanford University, Stanford, CA, 94305-3030, USACorrespondence[email protected].
,
Chong M Cha Center for Turbulence Research, Stanford University, Stanford, CA, 94305-3030, USA
&
Sergei Fedotov Department of Mathematics, UMIST, Manchester, M60 1QD, UK
Pages 317-332 | Received 18 Jun 2002, Published online: 17 Dec 2010

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Chunkan Yu, Felipe Minuzzi & Ulrich Maas. (2020) REDIM reduced chemistry for the simulation of counterflow diffusion flames with oscillating strain rates. Combustion Theory and Modelling 24:4, pages 682-704.
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Jesse Capecelatro, Daniel J. Bodony & Jonathan B. Freund. (2019) Adjoint-based sensitivity and ignition threshold mapping in a turbulent mixing layer. Combustion Theory and Modelling 23:1, pages 147-179.
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HossamA. El-Asrag, Heinz Pitsch, Wookyung Kim, Hyungrok Do & M. Godfrey Mungal. (2011) Damköhler Number Similarity for Static Flame Stability in Gaseous-Fueled Augmentor Flows. Combustion Science and Technology 183:7, pages 718-737.
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PAULE. DESJARDIN. (2005) MODELING OF CONDITIONAL DISSIPATION RATE FOR FLAMELET MODELS WITH APPLICATION TO LARGE EDDY SIMULATION OF FIRE PLUMES. Combustion Science and Technology 177:10, pages 1883-1916.
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J. XIAO, E. AUSTIN & W.L. ROBERTS. (2005) RELATIVE POLYCYCLIC AROMATIC HYDROCARBON CONCENTRATIONS IN UNSTEADY COUNTERFLOW DIFFUSION FLAMES. Combustion Science and Technology 177:4, pages 691-713.
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J.M. García-Oliver, J.M. Pastor, I. Olmeda, A. Kalbhor, D. Mira & J.A. van Oijen. (2024) LES of a pressurized sooting aero-engine model burner using a computationally efficient discrete sectional method coupled to tabulated chemistry. Combustion and Flame 260, pages 113198.
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Z. Sun, S. Gierth, M. Pollack, C. Hasse & A. Scholtissek. (2022) Ignition under strained conditions: Unsteady flamelet progress variable modeling for diesel engine conditions in the transient counterflow configuration. Combustion and Flame 240, pages 111841.
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Erica Quadarella, Junjun Guo, Alberto Cuoci & Hong G. Im. (2022) Flame-controlling continuation method for extinction of counterflow sooting flames with detailed chemistry. Flame-controlling continuation method for extinction of counterflow sooting flames with detailed chemistry.
J. Benajes, J.M. García-Oliver, J.M. Pastor, I. Olmeda, A. Both & D. Mira. (2022) Analysis of local extinction of a n-heptane spray flame using large-eddy simulation with tabulated chemistry. Combustion and Flame 235, pages 111730.
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Maryam Akram & Venkat Raman. (2021) Using approximate inertial manifold approach to model turbulent non-premixed combustion. Physics of Fluids 33:3.
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Hernan Olguin, Arne Scholtissek, Sebastian Gonzalez, Felipe Gonzalez, Matthias Ihme, Christian Hasse & Eva Gutheil. (2019) Closure of the scalar dissipation rate in the spray flamelet equations through a transport equation for the gradient of the mixture fraction. Combustion and Flame 208, pages 330-350.
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Tim Lackmann, Alan R. Kerstein & Michael Oevermann. (2018) A representative linear eddy model for simulating spray combustion in engines (RILEM). Combustion and Flame 193, pages 1-15.
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B. Wang, H. Chu, A. Kronenburg & O. T. Stein. 2018. High Performance Computing in Science and Engineering ' 17. High Performance Computing in Science and Engineering ' 17 205 220 .
J.P. White, S. Vilfayeau, A.W. Marshall, A. Trouvé & R.J. McDermott. (2017) Modeling flame extinction and reignition in large eddy simulations with fast chemistry. Fire Safety Journal 90, pages 72-85.
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T. Lackmann, J.C. Hewson, R.C. Knaus, A.R. Kerstein & M. Oevermann. (2017) Stochastic modeling of unsteady extinction in turbulent non-premixed combustion. Proceedings of the Combustion Institute 36:2, pages 1677-1684.
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S. Vilfayeau, J.P. White, P.B. Sunderland, A.W. Marshall & A. Trouvé. (2016) Large eddy simulation of flame extinction in a turbulent line fire exposed to air-nitrogen co-flow. Fire Safety Journal 86, pages 16-31.
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Zhao Yang, Xiangsheng Li, Zhenping Feng & Li Chen. (2016) Influence of mixing model constant on local extinction effects and temperature prediction in LES for non-premixed swirling diffusion flames. Applied Thermal Engineering 103, pages 243-251.
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Xuegang Li, Luhong Zhang, Yongli Sun, Bin Jiang, Xingang Li & Jun Wang. (2015) Numerical simulation of the flue gas side of refining vacuum furnace using CFD. Chemical Engineering Science 123, pages 70-80.
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Huangwei Zhang, Andrew Garmory, Davide E. Cavaliere & Epaminondas Mastorakos. (2015) Large Eddy Simulation/Conditional Moment Closure modeling of swirl-stabilized non-premixed flames with local extinction. Proceedings of the Combustion Institute 35:2, pages 1167-1174.
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Vivien R. Lecoustre, Paul G. Arias, Somesh P. Roy, Zhaoyu Luo, Dan C. Haworth, Hong G. Im, Tianfeng F. Lu & Arnaud Trouvé. (2014) Direct numerical simulations of non-premixed ethylene–air flames: Local flame extinction criterion. Combustion and Flame 161:11, pages 2933-2950.
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Yuan Xuan & Guillaume Blanquart. (2014) A flamelet-based a priori analysis on the chemistry tabulation of polycyclic aromatic hydrocarbons in non-premixed flames. Combustion and Flame 161:6, pages 1516-1525.
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Dirk Linse, Andreas Kleemann & Christian Hasse. (2014) Probability density function approach coupled with detailed chemical kinetics for the prediction of knock in turbocharged direct injection spark ignition engines. Combustion and Flame 161:4, pages 997-1014.
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John C. Hewson. (2013) An extinction criterion for nonpremixed flames subject to brief periods of high dissipation rates. Combustion and Flame 160:5, pages 887-897.
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K.P. Ruggirello, P.E. DesJardin, M.R. Baer, M.J. Kaneshige & E.S. Hertel. (2012) A reaction progress variable modeling approach for non-ideal multiphase explosives. International Journal of Multiphase Flow 42, pages 128-151.
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Kevin Ruggirello, Paul Desjardin, M Baer, Michael Kaneshige & Gene Hertel. (2012) A Reaction Progress Variable Modeling Approach for Non-Ideal Explosives. A Reaction Progress Variable Modeling Approach for Non-Ideal Explosives.
Shaukat Ali, Alexander Vikhansky & Terese Løvås. (2011) Direct Quadrature Conditional Moment Closure for Modelling of Turbulent Combustion. Flow, Turbulence and Combustion 87:2-3, pages 493-509.
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Dae Geun Park, Jin Han Yun, Jeong Park & Sang In Keel. (2009) A Study on Flame Extinction Characteristics along a C-Curve. Energy & Fuels 23:9, pages 4236-4244.
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R. Cònsul, A. Oliva, C.D. Pérez-Segarra, D. Carbonell & L.P.H. de Goey. (2008) Analysis of the flamelet concept in the numerical simulation of laminar partially premixed flames. Combustion and Flame 153:1-2, pages 71-83.
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Miguel Hermanns, Marcos Vera & Amable Liñán. (2007) On the dynamics of flame edges in diffusion-flame/vortex interactions. Combustion and Flame 149:1-2, pages 32-48.
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T. Mahmud, S.K. Sangha, M. Costa & A. Santos. (2007) Experimental and computational study of a lifted, non-premixed turbulent free jet flame. Fuel 86:5-6, pages 793-806.
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William Carnell & Michael Renfro. (2007) OH and CH2O Measurement and Simulation Through Local Extinction in Nonpremixed Flames. OH and CH2O Measurement and Simulation Through Local Extinction in Nonpremixed Flames.
Evatt R. Hawkes, Ramanan Sankaran, James C. Sutherland & Jacqueline H. Chen. (2007) Scalar mixing in direct numerical simulations of temporally evolving plane jet flames with skeletal CO/H2 kinetics. Proceedings of the Combustion Institute 31:1, pages 1633-1640.
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Chong M. Cha, Stephen M. de Bruyn Kops & Mikael Mortensen. (2006) Direct numerical simulations of the double scalar mixing layer. Part I: Passive scalar mixing and dissipation. Physics of Fluids 18:6.
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Forman Williams. (2006) Descriptions of Nonpremixed Turbulent Combustion. Descriptions of Nonpremixed Turbulent Combustion.
Matthias Ihme & Heinz Pitsch. (2005) LES of a Non-Premixed Flame Using an Extended Flamelet/Progress Variable Model. LES of a Non-Premixed Flame Using an Extended Flamelet/Progress Variable Model.
Guillaume Blanquart & Heinz Pitsch. (2005) Modeling autoignition in non-premixed turbulent combustion using a stochastic flamelet approach. Proceedings of the Combustion Institute 30:2, pages 2745-2753.
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Adonios N. Karpetis & Robert S. Barlow. (2005) Measurements of flame orientation and scalar dissipation in turbulent partially premixed methane flames. Proceedings of the Combustion Institute 30:1, pages 665-672.
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R. O. Fox & V. Raman. (2004) A multienvironment conditional probability density function model for turbulent reacting flows. Physics of Fluids 16:12, pages 4551-4565.
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C. Pantano & D.I. Pullin. (2004) A statistical description of turbulent diffusion flame holes. Combustion and Flame 137:3, pages 295-305.
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S. Mitarai, G. Kosály & J.J. Riley. (2004) A new Lagrangian flamelet model for local flame extinction and reignition. Combustion and Flame 137:3, pages 306-319.
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S. Mitarai, J. J. Riley & G. Kosály. (2003) A Lagrangian study of scalar diffusion in isotropic turbulence with chemical reaction. Physics of Fluids 15:12, pages 3856-3866.
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