With contributions from leading experts, this second volume in the series strikes a balance between generic and specific fundamentals and generic and specific applications. After opening with a broad overview of the field of high-performance scientific computing and its role in fluid flow and heat transfer problems, the book goes on to cover such topics as: unstructured meshes; spectral element method; use of the finite volume method for the numerical solution of radiative heat transfer problems; heat conduction and the use of the boundary element method for both steady and unsteady problems;…mehr
With contributions from leading experts, this second volume in the series strikes a balance between generic and specific fundamentals and generic and specific applications. After opening with a broad overview of the field of high-performance scientific computing and its role in fluid flow and heat transfer problems, the book goes on to cover such topics as: unstructured meshes; spectral element method; use of the finite volume method for the numerical solution of radiative heat transfer problems; heat conduction and the use of the boundary element method for both steady and unsteady problems; special numerical issues related to solving microscale heat transfer problems; the Monte Carlo Method; flow and heat transfer in porous media; and the thermal management of electronic systems.
1.High-Perfomance Computing for Fluid Flow and Heat Transfer 2.Unstructured Finite Volume Methods for Multi-Mode Heat Transfer 3.SpectralElement Methods for Unsteady Fluid Flow and Heat Transfer in Complex Geometries:Methodology and Applications 4.Finite-Volume Method for Radiation Heat Transfer 5.Boundary Element Methods for Heat Conduction 6.Molecular Dynamics Method for Microscale Heat Transfer 7.Numerical Methods in Microscale Heat Transfer:Modeling of Phase-Change and Laser Interactions with Materials 8.Current Status of the Use of Parallel Computing in Turbulent Reacting Flows:Computations Involving Sprays, Scalar Monte Carlo Probability Density Function and Unstructured Grids 9.Overview of Current Computational Studies of Heat Transfer in Porous Media and Their Applications-Forced Convection and Multiphase Heat Transfer 10.Overview of Current Computational Studies of Heat Transfer in Porous Media and Their Applications-Natural and Mixed Convection 11.Recent Progress and Some Challenges in Thermal Modeling of Electronic Systems 12.Index
1.High-Perfomance Computing for Fluid Flow and Heat Transfer 2.Unstructured Finite Volume Methods for Multi-Mode Heat Transfer 3.SpectralElement Methods for Unsteady Fluid Flow and Heat Transfer in Complex Geometries:Methodology and Applications 4.Finite-Volume Method for Radiation Heat Transfer 5.Boundary Element Methods for Heat Conduction 6.Molecular Dynamics Method for Microscale Heat Transfer 7.Numerical Methods in Microscale Heat Transfer:Modeling of Phase-Change and Laser Interactions with Materials 8.Current Status of the Use of Parallel Computing in Turbulent Reacting Flows:Computations Involving Sprays, Scalar Monte Carlo Probability Density Function and Unstructured Grids 9.Overview of Current Computational Studies of Heat Transfer in Porous Media and Their Applications-Forced Convection and Multiphase Heat Transfer 10.Overview of Current Computational Studies of Heat Transfer in Porous Media and Their Applications-Natural and Mixed Convection 11.Recent Progress and Some Challenges in Thermal Modeling of Electronic Systems 12.Index
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