Ebook: Multiscale Deformation and Fracture in Materials and Structures: The James R. Rice 60th Anniversary Volume
- Tags: Mechanics, Appl.Mathematics/Computational Methods of Engineering, Geotechnical Engineering
- Series: Solid Mechanics and Its Applications 84
- Year: 2002
- Publisher: Springer Netherlands
- Edition: 1
- Language: English
- pdf
Modern Solid Mechanics considers phenomena at many levels, ranging from nano size at atomic scale through the continuum level at millimeter size to large structures at the tens of meter scale. The deformation and fracture behavior at these various scales are inextricably related to interdisciplinary methods derived from applied mathematics, physics, chemistry, and engineering mechanics. This book, in honor of James R. Rice, contains articles from his colleagues and former students that bring these sophisticated methods to bear on a wide range of problems. Articles discussing problems of deformation include topics of dislocation mechanics, second particle effects, plastic yield criterion on porous materials, hydrogen embrittlement, solid state sintering, nanophases at surfaces, adhesion and contact mechanics, diffuse instability in geomaterials, and percolation in metal deformation. In the fracture area, the topics include: elastic-plastic crack growth, dynamic fracture, stress intensity and J-integral analysis, stress-corrosion cracking, and fracture in single crystal, piezoelectric, composite and cementitious materials.
The book will be a valuable resource for researchers in modern solid mechanics and can be used as reference or supplementary text in mechanical and civil engineering, applied mechanics, materials science, and engineering graduate courses on fracture mechanics, elasticity, plasticity, mechanics of materials or the application of solid mechanics to processing, and reliability of life predictions.
Modern Solid Mechanics considers phenomena at many levels, ranging from nano size at atomic scale through the continuum level at millimeter size to large structures at the tens of meter scale. The deformation and fracture behavior at these various scales are inextricably related to interdisciplinary methods derived from applied mathematics, physics, chemistry, and engineering mechanics. This book, in honor of James R. Rice, contains articles from his colleagues and former students that bring these sophisticated methods to bear on a wide range of problems. Articles discussing problems of deformation include topics of dislocation mechanics, second particle effects, plastic yield criterion on porous materials, hydrogen embrittlement, solid state sintering, nanophases at surfaces, adhesion and contact mechanics, diffuse instability in geomaterials, and percolation in metal deformation. In the fracture area, the topics include: elastic-plastic crack growth, dynamic fracture, stress intensity and J-integral analysis, stress-corrosion cracking, and fracture in single crystal, piezoelectric, composite and cementitious materials.
The book will be a valuable resource for researchers in modern solid mechanics and can be used as reference or supplementary text in mechanical and civil engineering, applied mechanics, materials science, and engineering graduate courses on fracture mechanics, elasticity, plasticity, mechanics of materials or the application of solid mechanics to processing, and reliability of life predictions.
Modern Solid Mechanics considers phenomena at many levels, ranging from nano size at atomic scale through the continuum level at millimeter size to large structures at the tens of meter scale. The deformation and fracture behavior at these various scales are inextricably related to interdisciplinary methods derived from applied mathematics, physics, chemistry, and engineering mechanics. This book, in honor of James R. Rice, contains articles from his colleagues and former students that bring these sophisticated methods to bear on a wide range of problems. Articles discussing problems of deformation include topics of dislocation mechanics, second particle effects, plastic yield criterion on porous materials, hydrogen embrittlement, solid state sintering, nanophases at surfaces, adhesion and contact mechanics, diffuse instability in geomaterials, and percolation in metal deformation. In the fracture area, the topics include: elastic-plastic crack growth, dynamic fracture, stress intensity and J-integral analysis, stress-corrosion cracking, and fracture in single crystal, piezoelectric, composite and cementitious materials.
The book will be a valuable resource for researchers in modern solid mechanics and can be used as reference or supplementary text in mechanical and civil engineering, applied mechanics, materials science, and engineering graduate courses on fracture mechanics, elasticity, plasticity, mechanics of materials or the application of solid mechanics to processing, and reliability of life predictions.
Content:
Front Matter....Pages i-xliv
Approximate Yield Criterion for Anisotropic Porous Sheet Metals and its Applications to Failure Prediction of Sheet Metals Under Forming Processes....Pages 1-15
A Dilatational Plasticity Theory for Aluminum Sheets....Pages 17-30
Internal Hydrogen-induced Embrittlement in Iron Single Crystals....Pages 31-47
A Comprehensive Model for Solid State Sintering and Its Application to Silicon Carbide....Pages 49-70
Mapping the Elastic-plastic Contact and Adhesion....Pages 71-85
The Critical Shear Stress to Transmit A Peierls Screw Dislocation Across A Non-slipping Interface....Pages 87-105
Self-organizing Nanophases on a Solid Surface....Pages 107-122
Elastic Space Containing A Rigid Ellipsoidal Inclusion Subjected to Translation and Rotation....Pages 123-143
Strain Percolation in Metal Deformation....Pages 145-157
Diffusive Instabilities in Dilating and Compacting Geomaterials....Pages 159-182
Fracture Mechanics of An Interface Crack between a Special Pair of Transversely Isotropic Materials....Pages 183-204
Path-independent Integrals Related to The J-integral and Their Evaluations....Pages 205-221
On the Extension of The Jr Concept to Significant Crack Growth....Pages 223-235
Effect of T-stress on Edge Dislocation Formation at A Crack Tip Under Mode I Loading....Pages 237-242
Elastic-plastic Crack Growth Along Ductile/Ductile Interfaces....Pages 243-274
Study of Crack Dynamics Using the Virtual Internal Bond Method....Pages 275-309
Crack Tip Plasticity in Copper Single Crystals....Pages 311-329
Numerical Simulations of Subcritical Crack Growth by Stress Corrosion in An Elastic Solid....Pages 331-348
Energy Release Rate for a Crack with Extrinsic Surface Charge in a Piezoelectric Compact Tension Specimen....Pages 349-359
Micromechanics of Failure in Composites....Pages 361-384
Back Matter....Pages 407-419
J-integral Applications to Characterization and Tailoring of Cementitious Materials....Pages 385-406
Modern Solid Mechanics considers phenomena at many levels, ranging from nano size at atomic scale through the continuum level at millimeter size to large structures at the tens of meter scale. The deformation and fracture behavior at these various scales are inextricably related to interdisciplinary methods derived from applied mathematics, physics, chemistry, and engineering mechanics. This book, in honor of James R. Rice, contains articles from his colleagues and former students that bring these sophisticated methods to bear on a wide range of problems. Articles discussing problems of deformation include topics of dislocation mechanics, second particle effects, plastic yield criterion on porous materials, hydrogen embrittlement, solid state sintering, nanophases at surfaces, adhesion and contact mechanics, diffuse instability in geomaterials, and percolation in metal deformation. In the fracture area, the topics include: elastic-plastic crack growth, dynamic fracture, stress intensity and J-integral analysis, stress-corrosion cracking, and fracture in single crystal, piezoelectric, composite and cementitious materials.
The book will be a valuable resource for researchers in modern solid mechanics and can be used as reference or supplementary text in mechanical and civil engineering, applied mechanics, materials science, and engineering graduate courses on fracture mechanics, elasticity, plasticity, mechanics of materials or the application of solid mechanics to processing, and reliability of life predictions.
Content:
Front Matter....Pages i-xliv
Approximate Yield Criterion for Anisotropic Porous Sheet Metals and its Applications to Failure Prediction of Sheet Metals Under Forming Processes....Pages 1-15
A Dilatational Plasticity Theory for Aluminum Sheets....Pages 17-30
Internal Hydrogen-induced Embrittlement in Iron Single Crystals....Pages 31-47
A Comprehensive Model for Solid State Sintering and Its Application to Silicon Carbide....Pages 49-70
Mapping the Elastic-plastic Contact and Adhesion....Pages 71-85
The Critical Shear Stress to Transmit A Peierls Screw Dislocation Across A Non-slipping Interface....Pages 87-105
Self-organizing Nanophases on a Solid Surface....Pages 107-122
Elastic Space Containing A Rigid Ellipsoidal Inclusion Subjected to Translation and Rotation....Pages 123-143
Strain Percolation in Metal Deformation....Pages 145-157
Diffusive Instabilities in Dilating and Compacting Geomaterials....Pages 159-182
Fracture Mechanics of An Interface Crack between a Special Pair of Transversely Isotropic Materials....Pages 183-204
Path-independent Integrals Related to The J-integral and Their Evaluations....Pages 205-221
On the Extension of The Jr Concept to Significant Crack Growth....Pages 223-235
Effect of T-stress on Edge Dislocation Formation at A Crack Tip Under Mode I Loading....Pages 237-242
Elastic-plastic Crack Growth Along Ductile/Ductile Interfaces....Pages 243-274
Study of Crack Dynamics Using the Virtual Internal Bond Method....Pages 275-309
Crack Tip Plasticity in Copper Single Crystals....Pages 311-329
Numerical Simulations of Subcritical Crack Growth by Stress Corrosion in An Elastic Solid....Pages 331-348
Energy Release Rate for a Crack with Extrinsic Surface Charge in a Piezoelectric Compact Tension Specimen....Pages 349-359
Micromechanics of Failure in Composites....Pages 361-384
Back Matter....Pages 407-419
J-integral Applications to Characterization and Tailoring of Cementitious Materials....Pages 385-406
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