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Combustion Theory and Modelling Volume 18, 2014 - Issue 3
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Original Articles

High-order algorithms for compressible reacting flow with complex chemistry

Matthew EmmettCenter for Computational Sciences and Engineering, Lawrence Berkeley National Laboratory, Berkeley, CA94720, USACorrespondence[email protected]
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,
Weiqun ZhangCenter for Computational Sciences and Engineering, Lawrence Berkeley National Laboratory, Berkeley, CA94720, USAView further author information
&
John B. BellCenter for Computational Sciences and Engineering, Lawrence Berkeley National Laboratory, Berkeley, CA94720, USAView further author information
Pages 361-387 | Received 27 Sep 2013, Accepted 23 Apr 2014, Published online: 28 May 2014

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M. Lucchesi, H. H. Alzahrani, C. Safta & O. M. Knio. (2019) A hybrid, non-split, stiff/RKC, solver for advection–diffusion–reaction equations and its application to low-Mach number combustion. Combustion Theory and Modelling 23:5, pages 935-955.
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Matthew Emmett, Emmanuel Motheau, Weiqun Zhang, Michael Minion & John B. Bell. (2019) A fourth-order adaptive mesh refinement algorithm for the multicomponent, reacting compressible Navier–Stokes equations. Combustion Theory and Modelling 23:4, pages 592-625.
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Andrew Nonaka, Marcus S. Day & John B. Bell. (2018) A conservative, thermodynamically consistent numerical approach for low Mach number combustion. Part I: Single-level integration. Combustion Theory and Modelling 22:1, pages 156-184.
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Su Cao, Beth Anne V. Bennett & Mitchell D. Smooke. (2015) MC-Smooth: A mass-conserving, smooth vorticity–velocity formulation for multi-dimensional flows. Combustion Theory and Modelling 19:6, pages 657-695.
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Articles from other publishers (19)

Daniel Mira, Eduardo J. Pérez-Sánchez, Ricard Borrell & Guillaume Houzeaux. (2023) HPC-enabling technologies for high-fidelity combustion simulations. Proceedings of the Combustion Institute 39:4, pages 5091-5125.
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Luc Vervisch, Pascale Domingo & John Bell. 2023. Numerical Methods in Turbulence Simulation. Numerical Methods in Turbulence Simulation 501 539 .
Marc T Henry de Frahan, Jon S Rood, Marc S Day, Hariswaran Sitaraman, Shashank Yellapantula, Bruce A Perry, Ray W Grout, Ann Almgren, Weiqun Zhang, John B Bell & Jacqueline H Chen. (2022) PeleC: An adaptive mesh refinement solver for compressible reacting flows. The International Journal of High Performance Computing Applications, pages 109434202211211.
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G. Saez-Mischlich, J. Sierra-Ausin, G. Grondin & J. Gressier. (2022) On the properties of high-order least-squares finite-volume schemes. Journal of Computational Physics 457, pages 111043.
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Emmanuel Motheau & John Wakefield. (2021) On the numerical accuracy in finite‐volume methods to accurately capture turbulence in compressible flows. International Journal for Numerical Methods in Fluids 93:10, pages 3020-3033.
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Ketan Mittal, Som Dutta & Paul Fischer. (2021) Multirate timestepping for the incompressible Navier-Stokes equations in overlapping grids. Journal of Computational Physics 437, pages 110335.
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Tao Li, Jiaying Pan, Fanfu Kong, Baopeng Xu & Xiaohan Wang. (2020) A quasi-direct numerical simulation solver for compressible reacting flows. Computers & Fluids 213, pages 104718.
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Majid Allahyari, Vahid Esfahanian & Kianoosh Yousefi. (2020) The Effects of Grid Accuracy on Flow Simulations: A Numerical Assessment. Fluids 5:3, pages 110.
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Emmanuel Motheau & John Wakefield. (2020) Investigation of finite-volume methods to capture shocks and turbulence spectra in compressible flows. Communications in Applied Mathematics and Computational Science 15:1, pages 1-36.
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M. Zingale, M. P. Katz, J. B. Bell, M. L. Minion, A. J. Nonaka & W. Zhang. (2019) Improved Coupling of Hydrodynamics and Nuclear Reactions via Spectral Deferred Corrections. The Astrophysical Journal 886:2, pages 105.
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Muhammad Nufail Farooqi, Tan Nguyen, Weiqun Zhang, Ann S. Almgren, John Shalf & Didem Unat. 2019. High Performance Computing. High Performance Computing 113 123 .
Muhammad Nufail Farooqi, Tan Nguyen, Weiqun Zhang, Ann S. Almgren, John Shalf & Didem Unat. (2018) Phase Asynchronous AMR Execution for Productive and Performant Astrophysical Flows. Phase Asynchronous AMR Execution for Productive and Performant Astrophysical Flows.
Tuowen Zhao, Samuel Williams, Mary Hall & Hans Johansen. (2018) Delivering Performance-Portable Stencil Computations on CPUs and GPUs Using Bricks. Delivering Performance-Portable Stencil Computations on CPUs and GPUs Using Bricks.
Andreas Naumann, Daniel Ruprecht & Joerg Wensch. (2018) Toward transient finite element simulation of thermal deformation of machine tools in real-time. Computational Mechanics 62:5, pages 929-942.
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Tuowen Zhao, Mary Hall, Protonu Basu, Samuel Williams & Hans Johansen. (2018) SIMD code generation for stencils on brick decompositions. ACM SIGPLAN Notices 53:1, pages 423-424.
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Daniel Ruprecht & Robert Speck. (2016) Spectral Deferred Corrections with Fast-wave Slow-wave Splitting. SIAM Journal on Scientific Computing 38:4, pages A2535-A2557.
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Weiqun Zhang, Ann Almgren, Marcus Day, Tan Nguyen, John Shalf & Didem Unat. (2016) BoxLib with Tiling: An Adaptive Mesh Refinement Software Framework. SIAM Journal on Scientific Computing 38:5, pages S156-S172.
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Didem Unat, Tan Nguyen, Weiqun Zhang, Muhammed Nufail Farooqi, Burak Bastem, George Michelogiannakis, Ann Almgren & John Shalf. 2016. High Performance Computing. High Performance Computing 116 135 .
Didem Unat, Cy Chan, Weiqun Zhang, Samuel Williams, John Bachan, John Bell & John Shalf. (2015) ExaSAT: An exascale co-design tool for performance modeling. The International Journal of High Performance Computing Applications 29:2, pages 209-232.
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