This book summarizes, defines, and contextualizes multiphysics with an emphasis on porous materials. It covers various essential aspects of multiphysics, from history, definition, and scope to mathematical theories, physical mechanisms, and numerical implementations. The emphasis on porous materials maximizes readers' understanding as these substances are abundant in nature and a common breeding ground of multiphysical phenomena, especially complicated multiphysics. Dr. Liu's lucid and easy-to-follow presentation serve as a blueprint on the use of multiphysics as a leading edge technique for…mehr
This book summarizes, defines, and contextualizes multiphysics with an emphasis on porous materials. It covers various essential aspects of multiphysics, from history, definition, and scope to mathematical theories, physical mechanisms, and numerical implementations. The emphasis on porous materials maximizes readers' understanding as these substances are abundant in nature and a common breeding ground of multiphysical phenomena, especially complicated multiphysics. Dr. Liu's lucid and easy-to-follow presentation serve as a blueprint on the use of multiphysics as a leading edge technique for computer modeling. The contents are organized to facilitate the transition from familiar, monolithic physics such as heat transfer and pore water movement to state-of-the-art applications involving multiphysics, including poroelasticity, thermohydro-mechanical processes, electrokinetics, electromagnetics, fluid dynamics, fluid structure interaction, and electromagnetomechanics. This volume serves as both a general reference and specific treatise for various scientific and engineering disciplines involving multiphysics simulation and porous materials.
Dr. Zhen Liu is a faculty member at Michigan Technological University in Houghton, Michigan. Dr. Liu has over ten years of experience in various multiphysics topics including thermomechanics, thermohydromechanical processes, poroelasticity, electrokinetics, fluid-structure interaction, non-isothermal buoyancy-driven flow, mechanical and electromagnetic waves, heating with electromagnetics, piezoelectric and triboelectric applications, and so on. His work has been applied to the safety, sustainability, energy, and artificial intelligence aspects of geosystems consisting of porous materials such as soils and cement-based materials. In addition, Dr. Liu has been focusing on the scientific understanding of couplings between physical fields in porous materials such as the stress formulation, thermally-induced water flux, wettability and adsorption of minerals, electrokinetic fluxes, and phase changes. Besides research, Dr. Liu has been offering one of the first graduate-level multiphysics courses with a focus on the mathematics, physics, application, and implementations of multiphysics around the world. He has also been leading a community-level education and outreach effort for developing a general learning and networking website for multiphysics.
Inhaltsangabe
Part 1 IntroductionChapter 1 History and FutureChapter 2 What is MultiphysicsChapter 3 How to Do MultiphysicsChapter 4 Multiphysics in Porous MaterialsChapter 5 How to Use this BookPart 2 Mathematical BackgroundChapter 6 Tensor and FieldChapter 7 Tensor AnalysisChapter 8 Index Notation and Tensor NotationChapter 9 Partial Differential EquationsChapter 10 Numerical Solution of PDEsPart 3 Monolithic PhysicsChapter 11 Thermo: Heat TransferChapter 12 Hydro: Pore Water MovementChapter 13 Concentrato: Transport of Dispersed MassChapter 14 Mechano: Stress and StrainChapter 15 Dyno: DynamicsChapter 16 Chemico: Chemical ReactionChapter 17 Electro: ElectrostaticsChapter 18 Magneto: MagnetostaticsPart 4 MultiphysicsChapter 19 Thermomechanics: Non-Isothermal MechanicsChapter 20 Hydromechanics: Poroelasticity as a Simple CaseChapter 21 ThermohydromechanicsChapter 22 ElectrokineticsChapter 23 ElectromagneticsChapter 24 Fluid DynamicsChapter 25 Hydrodynomechanics: Fluid-Structure InteractionChapter 26 ThermoelectromagneticsChapter 27 ElectromagnetomechanicsPart 5 Implementation MethodsChapter 28 Finite Difference MethodChapter 29 Finite Volume MethodChapter 30 Finite Element MethodReferencesIndex
Part 1 Introduction Chapter 1 History and Future Chapter 2 What is Multiphysics Chapter 3 How to Do Multiphysics Chapter 4 Multiphysics in Porous Materials Chapter 5 How to Use this Book Part 2 Mathematical Background Chapter 6 Tensor and Field Chapter 7 Tensor Analysis Chapter 8 Index Notation and Tensor Notation Chapter 9 Partial Differential Equations Chapter 10 Numerical Solution of PDEs Part 3 Monolithic Physics Chapter 11 Thermo: Heat Transfer Chapter 12 Hydro: Pore Water Movement Chapter 13 Concentrato: Transport of Dispersed Mass Chapter 14 Mechano: Stress and Strain Chapter 15 Dyno: Dynamics Chapter 16 Chemico: Chemical Reaction Chapter 17 Electro: Electrostatics Chapter 18 Magneto: Magnetostatics Part 4 Multiphysics Chapter 19 Thermomechanics: Non-Isothermal Mechanics Chapter 20 Hydromechanics: Poroelasticity as a Simple Case Chapter 21 Thermohydromechanics Chapter 22 Electrokinetics Chapter 23 Electromagnetics Chapter 24 Fluid Dynamics Chapter 25 Hydrodynomechanics: Fluid-Structure Interaction Chapter 26 Thermoelectromagnetics Chapter 27 Electromagnetomechanics Part 5 Implementation Methods Chapter 28 Finite Difference Method Chapter 29 Finite Volume Method Chapter 30 Finite Element Method References Index
Part 1 IntroductionChapter 1 History and FutureChapter 2 What is MultiphysicsChapter 3 How to Do MultiphysicsChapter 4 Multiphysics in Porous MaterialsChapter 5 How to Use this BookPart 2 Mathematical BackgroundChapter 6 Tensor and FieldChapter 7 Tensor AnalysisChapter 8 Index Notation and Tensor NotationChapter 9 Partial Differential EquationsChapter 10 Numerical Solution of PDEsPart 3 Monolithic PhysicsChapter 11 Thermo: Heat TransferChapter 12 Hydro: Pore Water MovementChapter 13 Concentrato: Transport of Dispersed MassChapter 14 Mechano: Stress and StrainChapter 15 Dyno: DynamicsChapter 16 Chemico: Chemical ReactionChapter 17 Electro: ElectrostaticsChapter 18 Magneto: MagnetostaticsPart 4 MultiphysicsChapter 19 Thermomechanics: Non-Isothermal MechanicsChapter 20 Hydromechanics: Poroelasticity as a Simple CaseChapter 21 ThermohydromechanicsChapter 22 ElectrokineticsChapter 23 ElectromagneticsChapter 24 Fluid DynamicsChapter 25 Hydrodynomechanics: Fluid-Structure InteractionChapter 26 ThermoelectromagneticsChapter 27 ElectromagnetomechanicsPart 5 Implementation MethodsChapter 28 Finite Difference MethodChapter 29 Finite Volume MethodChapter 30 Finite Element MethodReferencesIndex
Part 1 Introduction Chapter 1 History and Future Chapter 2 What is Multiphysics Chapter 3 How to Do Multiphysics Chapter 4 Multiphysics in Porous Materials Chapter 5 How to Use this Book Part 2 Mathematical Background Chapter 6 Tensor and Field Chapter 7 Tensor Analysis Chapter 8 Index Notation and Tensor Notation Chapter 9 Partial Differential Equations Chapter 10 Numerical Solution of PDEs Part 3 Monolithic Physics Chapter 11 Thermo: Heat Transfer Chapter 12 Hydro: Pore Water Movement Chapter 13 Concentrato: Transport of Dispersed Mass Chapter 14 Mechano: Stress and Strain Chapter 15 Dyno: Dynamics Chapter 16 Chemico: Chemical Reaction Chapter 17 Electro: Electrostatics Chapter 18 Magneto: Magnetostatics Part 4 Multiphysics Chapter 19 Thermomechanics: Non-Isothermal Mechanics Chapter 20 Hydromechanics: Poroelasticity as a Simple Case Chapter 21 Thermohydromechanics Chapter 22 Electrokinetics Chapter 23 Electromagnetics Chapter 24 Fluid Dynamics Chapter 25 Hydrodynomechanics: Fluid-Structure Interaction Chapter 26 Thermoelectromagnetics Chapter 27 Electromagnetomechanics Part 5 Implementation Methods Chapter 28 Finite Difference Method Chapter 29 Finite Volume Method Chapter 30 Finite Element Method References Index
Es gelten unsere Allgemeinen Geschäftsbedingungen: www.buecher.de/agb
Impressum
www.buecher.de ist ein Shop der buecher.de GmbH & Co. KG Bürgermeister-Wegele-Str. 12, 86167 Augsburg Amtsgericht Augsburg HRA 13309