05598nam 2200685Ia 450 991046479000332120200520144314.01-283-85062-11-84816-664-8(CKB)3400000000087182(EBL)1080990(OCoLC)817581654(SSID)ssj0000789185(PQKBManifestationID)12325950(PQKBTitleCode)TC0000789185(PQKBWorkID)10726008(PQKB)10573233(MiAaPQ)EBC1080990(WSP)00002804(Au-PeEL)EBL1080990(CaPaEBR)ebr10627516(CaONFJC)MIL416312(EXLCZ)99340000000008718220120626d2013 uy 0engur|n|---|||||txtccrFracture mechanics of electromagnetic materials[electronic resource] nonlinear field theory and applications /Xiaohong Chen, Yiu-Wing MaiLondon Imperial College Press ;Singapore ;Hackensack, NJ Distributed by World Scientificc20131 online resource (326 p.)Description based upon print version of record.1-84816-663-X Includes bibliographical references (p. 276-298) and index.Foreword; Preface; Contents; List of Tables; List of Figures; Chapter 1: Fundamentals of Fracture Mechanics; 1.1 Historical Perspective; 1.2 Stress Intensity Factors (SIF); 1.3 Energy Release Rate (ERR); 1.4 J-Integral; 1.5 Dynamic Fracture; 1.6 Viscoelastic Fracture; 1.7 Essential Work of Fracture (EWF); 1.8 Configuration Force (Material Force) Method; 1.9 Cohesive Zone and Virtual Internal Bond Models; Chapter 2 : Elements of Electrodynamics of Continua; 2.1 Notations; 2.1.1 Eulerian and Lagrangian descriptions; 2.1.2 Electromagnetic field; 2.1.3 Electromagnetic body force and couple2.1.4 Electromagnetic stress tensor and momentum vector2.1.5 Electromagnetic power; 2.1.6 Poynting theorem; 2.2 Maxwell Equations; 2.3 Balance Equations of Mass, Momentum, Moment of Momentum, and Energy; 2.4 Constitutive Relations; 2.5 Linearized Theory; Chapter 3 : Introduction to Thermoviscoelasticity; 3.1 Thermoelasticity; 3.2 Viscoelasticity; 3.3 Coupled Theory of Thermoviscoelasticity; 3.3.1 Fundamental principles of thermodynamics; 3.3.2 Formulation based on Helmholtz free energy functional; 3.3.3 Formulation based on Gibbs free energy functional3.4 Thermoviscoelastic Boundary-Initial Value ProblemsChapter 4 : Overview on Fracture of Electromagnetic Materials; 4.1 Introduction; 4.2 Basic Field Equations; 4.3 General Solution Procedures; 4.4 Debates on Crack-Face Boundary Conditions; 4.5 Fracture Criteria; 4.5.1 Field intensity factors; 4.5.2 Path-independent integral; 4.5.3 Mechanical strain energy release rate; 4.5.4 Global and local energy release rates; 4.6 Experimental Observations; 4.6.1 Indentation test; 4.6.2 Compact tension test; 4.6.3 Bending test; 4.7 Nonlinear Studies; 4.7.1 Electrostriction/magnetostriction4.7.2 Polarization/magnetization saturation4.7.3 Domain switching; 4.7.4 Domain wall motion; 4.8 Status and Prospects; Chapter 5 : Crack Driving Force in Electro-Thermo-Elastodynamic Fracture; 5.1 Introduction; 5.2 Fundamental Principles of Thermodynamics; 5.3 Energy Flux and Dynamic Contour Integral; 5.4 Dynamic Energy Release Rate Serving as Crack Driving Force; 5.5 Configuration Force and Energy-Momentum Tensor; 5.6 Coupled Electromechanical Jump/Boundary Conditions; 5.7 Asymptotic Near-Tip Field Solution; 5.8 RemarksChapter 6 : Dynamic Fracture Mechanics of Magneto-Electro-Thermo-Elastic Solids6.1 Introduction; 6.2 Thermodynamic Formulation of Fully Coupled Dynamic Framework; 6.2.1 Field equations and jump conditions; 6.2.2 Dynamic energy release rate; 6.2.3 Invariant integral; 6.3 Stroh-Type Formalism for Steady-State Crack Propagation under Coupled Magneto-Electro-Mechanical Jump/Boundary Conditions; 6.3.1 Generalized plane crack problem; 6.3.2 Steady-state solution; 6.3.3 Path-independent integral for steady crack growth; 6.4 Magneto-Electro-Elastostatic Crack Problem as a Special Case; 6.5 SummaryChapter 7 : Dynamic Crack Propagation in Magneto-Electro-Elastic SolidsFracture Mechanics of Electromagnetic Materials provides a comprehensive overview of fracture mechanics of conservative and dissipative materials, as well as a general formulation of nonlinear field theory of fracture mechanics and a rigorous treatment of dynamic crack problems involving coupled magnetic, electric, thermal and mechanical field quantities.Thorough emphasis is placed on the physical interpretation of fundamental concepts, development of theoretical models and exploration of their applications to fracture characterization in the presence of magneto-electro-thermo-mechanical couplFracture mechanicsMathematicsNonlinear theoriesMagnetic materialsFractureElectronic books.Fracture mechanicsMathematics.Nonlinear theories.Magnetic materialsFracture.620.1/126620.1126Chen Xiaohong1044527Mai Y. W.1946-932011MiAaPQMiAaPQMiAaPQBOOK9910464790003321Fracture mechanics of electromagnetic materials2470251UNINA