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Multiphase lattice Boltzmann methods : theory and application / Haibo Huang, Michael C. Sukop, and Xi-Yun Lu.

By: Contributor(s): Material type: TextTextPublisher: Chichester, West Sussex, UK : Hoboken, New Jersey John Wiley and Sons, Inc., 2015Description: 1 online resourceContent type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781118971345 (epub)
  • 1118971345 (epub)
  • 9781118971444 (pdf)
  • 1118971442 (pdf)
  • 9781118971451
  • 1118971450
Subject(s): Genre/Form: Additional physical formats: Print version:: Multiphase lattice Boltzmann methodsDDC classification:
  • 530.13/2 23
LOC classification:
  • TA357.5.M84
Online resources:
Contents:
2.1.1 ""Equilibrium"" velocity in the SC model2.1.2 Inter-particle forces in the SC SCMP LBM; 2.2 Typical equations of state; 2.2.1 Parameters in EOS; 2.3 Thermodynamic consistency; 2.3.1 The SCMP LBM EOS; 2.3.2 Incorporating other EOS into the SC model; 2.4 Analytical surface tension; 2.4.1 Inter-particle Force Model A; 2.4.2 Inter-particle Force Model B; 2.5 Contact angle; 2.6 Capillary rise; 2.7 Parallel flow and relative permeabilities; 2.8 Forcing term in the SC model; 2.8.1 Schemes to incorporate the body force; 2.8.2 Scheme overview; 2.8.3 Theoretical analysis.
2.8.4 Numerical results and discussion2.9 Multirange pseudopotential (Inter-particle Force Model B); 2.10 Conclusions; 2.11 Appendix A: Analytical solution for layered multiphase flow in a channel; 2.12 Appendix B: FORTRAN code to simulate single component multiphase droplet contacting a wall, as shown in Figure 2.7(c); Chapter 3 Shan and Chen-type multi-component multiphase models; 3.1 Multi-component multiphase SC LBM; 3.1.1 Fluid-fluid cohesion and fluid-solid adhesion; 3.2 Derivation of the pressure; 3.2.1 Pressure in popular papers (2D); 3.2.2 Pressure in popular papers (3D).
3.3 Determining Gc and the surface tension3.4 Contact angle; 3.4.1 Application of Young's equation to MCMP LBM; 3.4.2 Contact angle measurement; 3.4.3 Verification of proposed equation; 3.5 Flow through capillary tubes; 3.6 Layered two-phase flow in a 2D channel; 3.7 Pressure or velocity boundary conditions; 3.7.1 Boundary conditions for 2D simulations; 3.7.2 Boundary conditions for 3D simulations; 3.8 Displacement in a 3D porous medium; Chapter 4 Rothman-Keller multiphase Lattice Boltzmann model; 4.1 Introduction; 4.2 RK color-gradient model.
4.3 Theoretical analysis (Chapman-Enskog expansion)4.3.1 Discussion of above formulae; 4.4 Layered two-phase flow in a 2D channel; 4.4.1 Cases of two fluids with identical densities; 4.4.2 Cases of two fluids with different densities; 4.5 Interfacial tension and isotropy of the RK model; 4.5.1 Interfacial tension; 4.5.2 Isotropy; 4.6 Drainage and capillary filling; 4.7 MRT RK model; 4.8 Contact angle; 4.8.1 Spurious currents; 4.9 Tests of inlet/outlet boundary conditions; 4.10 Immiscible displacements in porous media; 4.11 Appendix A; 4.12 Appendix B.
Summary: Theory and Application of Multiphase Lattice Boltzmann Methods presents a comprehensive review of all popular multiphase Lattice Boltzmann Methods developed thus far and is aimed at researchers and practitioners within relevant Earth Science disciplines as well as Petroleum, Chemical, Mechanical and Geological Engineering. Clearly structured throughout, this book will be an invaluable reference on the current state of all popular multiphase Lattice Boltzmann Methods (LBMs). The advantages and disadvantages of each model are presented in an accessible manner to enable the reader to choose the.
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Includes bibliographical references and index.

Description based on print version record and CIP data provided by publisher.

880-01 2.1.1 ""Equilibrium"" velocity in the SC model2.1.2 Inter-particle forces in the SC SCMP LBM; 2.2 Typical equations of state; 2.2.1 Parameters in EOS; 2.3 Thermodynamic consistency; 2.3.1 The SCMP LBM EOS; 2.3.2 Incorporating other EOS into the SC model; 2.4 Analytical surface tension; 2.4.1 Inter-particle Force Model A; 2.4.2 Inter-particle Force Model B; 2.5 Contact angle; 2.6 Capillary rise; 2.7 Parallel flow and relative permeabilities; 2.8 Forcing term in the SC model; 2.8.1 Schemes to incorporate the body force; 2.8.2 Scheme overview; 2.8.3 Theoretical analysis.

2.8.4 Numerical results and discussion2.9 Multirange pseudopotential (Inter-particle Force Model B); 2.10 Conclusions; 2.11 Appendix A: Analytical solution for layered multiphase flow in a channel; 2.12 Appendix B: FORTRAN code to simulate single component multiphase droplet contacting a wall, as shown in Figure 2.7(c); Chapter 3 Shan and Chen-type multi-component multiphase models; 3.1 Multi-component multiphase SC LBM; 3.1.1 Fluid-fluid cohesion and fluid-solid adhesion; 3.2 Derivation of the pressure; 3.2.1 Pressure in popular papers (2D); 3.2.2 Pressure in popular papers (3D).

3.3 Determining Gc and the surface tension3.4 Contact angle; 3.4.1 Application of Young's equation to MCMP LBM; 3.4.2 Contact angle measurement; 3.4.3 Verification of proposed equation; 3.5 Flow through capillary tubes; 3.6 Layered two-phase flow in a 2D channel; 3.7 Pressure or velocity boundary conditions; 3.7.1 Boundary conditions for 2D simulations; 3.7.2 Boundary conditions for 3D simulations; 3.8 Displacement in a 3D porous medium; Chapter 4 Rothman-Keller multiphase Lattice Boltzmann model; 4.1 Introduction; 4.2 RK color-gradient model.

4.3 Theoretical analysis (Chapman-Enskog expansion)4.3.1 Discussion of above formulae; 4.4 Layered two-phase flow in a 2D channel; 4.4.1 Cases of two fluids with identical densities; 4.4.2 Cases of two fluids with different densities; 4.5 Interfacial tension and isotropy of the RK model; 4.5.1 Interfacial tension; 4.5.2 Isotropy; 4.6 Drainage and capillary filling; 4.7 MRT RK model; 4.8 Contact angle; 4.8.1 Spurious currents; 4.9 Tests of inlet/outlet boundary conditions; 4.10 Immiscible displacements in porous media; 4.11 Appendix A; 4.12 Appendix B.

Theory and Application of Multiphase Lattice Boltzmann Methods presents a comprehensive review of all popular multiphase Lattice Boltzmann Methods developed thus far and is aimed at researchers and practitioners within relevant Earth Science disciplines as well as Petroleum, Chemical, Mechanical and Geological Engineering. Clearly structured throughout, this book will be an invaluable reference on the current state of all popular multiphase Lattice Boltzmann Methods (LBMs). The advantages and disadvantages of each model are presented in an accessible manner to enable the reader to choose the.

Physical Science