LEADER 05503nam  2200697Ia 450 
001 9910784561903321
005 20200520144314.0
010   $a1-281-04671-X
010   $a9786611046712
010   $a0-08-053363-9
035   $a(CKB)1000000000363874
035   $a(EBL)313904
035   $a(OCoLC)647656439
035   $a(SSID)ssj0000298201
035   $a(PQKBManifestationID)11947392
035   $a(PQKBTitleCode)TC0000298201
035   $a(PQKBWorkID)10344063
035   $a(PQKB)10287516
035   $a(MiAaPQ)EBC313904
035   $a(Au-PeEL)EBL313904
035   $a(CaPaEBR)ebr10191638
035   $a(CaONFJC)MIL104671
035   $a(OCoLC)935264301
035   $a(PPN)260920835
035   $a(EXLCZ)991000000000363874
100   $a20010430d2001      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aHandbook of materials behavior models$hVolume 1$iDeformations of materials$b[electronic resource] /$feditor Jean Lemaitre
210   $aSan Diego, CA $cAcademic$dc2001
215   $a1 online resource (1231 p.)
300   $aDescription based upon print version of record.
311   $a0-12-443341-3 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Handbook of Materials Behavior Models; Copyright Page; Contents; Chapter 1. Background on mechanics of materials; 1.1 Background on modeling; 1.2 Materials and process selection; 1.3 Size effect on structural strength; Chapter 2. Elasticity, viscoelasticity; 2.1 Introduction to elasticity and viscoelasticity; 2.2 Background on nonlinear elasticity; 2.3 Elasticity of porous materials; 2.4 Elastomer models; 2.5 Background on viscoelasticity; 2.6 A nonlinear viscoelastic model based on fluctuating modes; 2.7 Linear viscoelasticity with damage; Chapter 3. Yield limit
327   $a3.1 Introduction to yield limits3.2 Background on isotropic criteria; 3.3 Yield loci based on crystallographic texture; 3.4 Anisotropic yield conditions; 3.5 Distortional model of plastic hardening; 3.6 A generalized limit criterion with application to strength, yielding, and damage of isotropic materials; 3.7 Yield conditions in beams, plates, and shells; Chapter 4. Plasticity; 4.1 Introduction to plasticity; 4.2 Elastoplasticity of metallic polycrystals by the self-consistent model; 4.3 Anisotropic elastoplastic model based on crystallographic texture
327   $a4.4 Cyclic plasticity model with nonlinear isotropic and kinematic hardening: No LIKH model4.5 Multisurface hardening model for monotonic and cyclic response of metals; 4.6 Kinematic hardening rule with critical state of dynamic recovery; 4.7 Kinematic hardening rule for biaxial ratcheting; 4.8 Plasticity in large deformations; 4.9 Plasticity of polymers; 4.10 Rational phenomenology in dynamic plasticity; 4.11 Conditions for localization in plasticity and rate-independent materials; 4.12 An introduction to gradient plasticity; Chapter 5. Viscoplasticity; 5.1 Introduction to viscoplasticity
327   $a5.2 A phenomenological anisotropic creep model for cubic single crystals5.3 Crystalline viscoplasticity applied to single crystals; 5.4 Averaging of viscoplastic polycrystalline materials with the tangent self-consistent model; 5.5 Fraction models for inelastic deformation; 5.6 Inelastic compressible and incompressible, isotropic, small-strain viscoplasticity theory based on overstress (VBO); 5.7 An outline of the Bodner-Partom (BP) unified constitutive equations for elastic-viscoplastic behavior; 5.8 Unified model of cyclic viscoplasticity based on the nonlinear kinematic hardening rule
327   $a5.9 A model of nonproportional cyclic viscoplasticity5.10 Rate-dependent elastoplastic constitutive relations; 5.11 Physically based rate- and temperature-dependent constitutive models for metals; 5.12 Elastic-viscoplastic deformation of polymers; Chapter 6. Continuous damage; 6.1 Introduction to continuous damage; 6.2 Damage-equivalent stress-fracture criterion; 6.3 Micromechanically inspired continuous models of brittle damage; 6.4 Anisotropic damage; 6.5 Modified Gurson model; 6.6 The Rousselier model for porous metal plasticity and ductile fracture; 6.7 Model of anisotropic creep damage
327   $a6.8 Multiaxial fatigue damage criteria
330   $aThis first of a kind reference/handbook deals with nonlinear models and properties of material. In the study the behavior of materials' phenomena no unique laws exist. Therefore, researchers often turn to models to determine the properties of materials.  This will be the first book to bring together such a comprehensive collection of these models.The Handbook deals with all solid materials, and is organized first by phenomena. Most of the materials models presented in an applications-oriented fashion, less descriptive and more practitioner-geared, making it useful in the daily w
606   $aMaterials
606   $aMaterials$xSimulation methods
606   $aMaterials$vHandbooks, manuals, etc
615  0$aMaterials.
615  0$aMaterials$xSimulation methods.
615  0$aMaterials
676   $a620.1/1/015118 21
676   $a620.11015118
676   $a620.112
701   $aLemai?tre$b J$g(Jean),$f1934-$029305
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910784561903321
996   $aHandbook of materials behavior models$93708333
997   $aUNINA