BookDOI
Micromechanics and Inhomogeneity
G.J. Weng,M. Taya,H. Abe +2 more
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TLDR
In this paper, the authors present articles on micromechanics and inhomogeneity in the field of mechanics of materials, which is a recognized discipline in the study of materials.Abstract:
Micromechanics has emerged as a recognized discipline in the study of mechanics of materials. This book contains articles on micromechanics and inhomogeneity.read more
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Journal ArticleDOI
Shape memory alloys, Part I: General properties and modeling of single crystals
TL;DR: In this article, a review of shape memory alloys (SMAs) constitutive behavior is presented, including shape memory effect, pseudoelasticity, damping capacity and fatigue life.
Journal ArticleDOI
Size-Dependent Eshelby’s Tensor for Embedded Nano-Inclusions Incorporating Surface/Interface Energies
Pradeep Sharma,S. Ganti +1 more
TL;DR: In this paper, a modified version of the Eshelby tensor tensor for nano-inclusions is presented, where the elastic state of an embedded inclusion is modified by incorporating the previously excluded surface/interface Stresses, tension and energies.
Journal ArticleDOI
On transformation strains and uniform fields in multiphase elastic media
George J. Dvorak,Y. Benveniste +1 more
TL;DR: In this article, the effect of local eigenstrain and eigenstress fields on the local strains and stresses is explored in multiphase elastic solids of arbitrary geometry and material symmetry.
Journal ArticleDOI
Two scale analysis of heterogeneous elastic-plastic materials with asymptotic homogenization and Voronoi cell finite element model
TL;DR: In this paper, a multiple scale finite element model (VCFEM-HOMO) was developed for elastic-plastic analysis of heterogeneous (porous and composite) materials by combining asymptotic homogenization theory with the Voronoi Cell finite element models.
Journal ArticleDOI
Effect of grain size on mechanical properties of nanocrystalline materials
TL;DR: In this article, the possibility of a dislocation mechanism in the deformation process of nanocrystalline materials is reviewed and analyzed, by taking the anisotropic characteristic of crystallographic symmetry and different choices of critical shear strength into account, results in a reasonable limit in grain size for applying dislocation pile-up theory to nanocrystine materials.