| List of Figures | p. xi |
| List of Tables | p. xv |
| Preface | p. xvii |
| Acknowledgments | p. xxi |
| Historical Review and Fundamentals | p. 1 |
| Definitions and basic formulations | p. 2 |
| Definitions of the J[subscript k] integral vector, M integral, and L integral | p. 2 |
| Path selections and conservation laws | p. 6 |
| Discussion of previous investigations for invariant integrals | p. 20 |
| Physical meanings of the M integral and the L integral | p. 23 |
| Nondestructive evaluation of the J and M integrals | p. 27 |
| Techniques for experimentally evaluating J and M | p. 28 |
| Edge crack | p. 29 |
| Evaluation of the M integral | p. 31 |
| Center crack | p. 33 |
| Brief Summary | p. 35 |
| Conservation Laws in Brittle Solids | p. 41 |
| Historical reviews and engineering backgrounds | p. 42 |
| Independence of the M integral from the origin selection of the global coordinates | p. 44 |
| Application of the M integral in multiple crack interacting problems | p. 45 |
| Independence of the M integral from the origin selection of the coordinates | p. 47 |
| Numerical examples | p. 50 |
| Four regularly distributed microcracks | p. 50 |
| Randomly distributed microcracks | p. 56 |
| Short summary | p. 61 |
| Conservation laws in bimaterials | p. 62 |
| Conservation laws of the J[subscript k] vector in bimaterials | p. 63 |
| Independence of the M integral from the coordinate selection in bimaterials | p. 69 |
| M integral analysis for microcrack damage in the brittle phase | p. 74 |
| A half-plane brittle solid containing multiple cracks | p. 86 |
| Brief summary | p. 87 |
| The Projected Conservation Law of J[subscript K] Vector in Microcrack Shielding Problems | p. 95 |
| Microcrack shielding problems | p. 96 |
| A continuum theory of microcrack shielding | p. 97 |
| A discrete modelling of shielding problems | p. 104 |
| Fundamental solutions | p. 105 |
| Pseudo-traction methods and integral equations | p. 108 |
| Numerical examinations | p. 114 |
| The J integral analysis: the projected conservation law of the Jk vector | p. 115 |
| Numerical results and discussions | p. 118 |
| Effect of the T stress | p. 120 |
| What is the T stress? | p. 120 |
| What role does the T stress play in microcrack shielding problems? | p. 122 |
| Brief summary | p. 128 |
| Application of the Conservation Laws in Metal/Ceramic Bimaterials | p. 135 |
| Fundamental solutions for an interface crack and a sub-interface crack | p. 137 |
| Pseudo-traction methods and Fredholm integral equations | p. 145 |
| The J integral analysis: the projected conservation law of the J[subscript k] vector | p. 153 |
| Numerical examples and discussions | p. 159 |
| Brief summary | p. 164 |
| Macrocrack Microcrack Interaction in Dissimilar Anisotropic Materials | p. 171 |
| Fundamental formulations in dissimilar anisotropic materials | p. 172 |
| Fundamental solution for an interface crack | p. 174 |
| Fundamental solution for an edge dislocation | p. 176 |
| Remote loading conditions | p. 179 |
| Superimposing technique and singular integral equations | p. 179 |
| Decomposition of the original problem | p. 179 |
| Solution of the integral equations | p. 182 |
| Analysis of the J integral | p. 184 |
| Conservation law of the J integral | p. 184 |
| Calculation of the J[subscript 2] integral | p. 186 |
| Multiple microcracks situation | p. 187 |
| Numerical results and consistency check | p. 188 |
| Composite material properties | p. 188 |
| Crack interaction configuration and numerical results | p. 188 |
| In homogeneous anisotropic cases | p. 190 |
| Different dissimilar materials combinations | p. 190 |
| The T stress effect | p. 196 |
| Brief Summary | p. 198 |
| Macrocrack Microcrack Interaction in Piezoelectric Materials | p. 203 |
| Elementary solutions | p. 204 |
| Elementary solutions for a finite crack | p. 206 |
| Elementary solutions for a semi-infinite crack | p. 208 |
| Remote loading conditions | p. 209 |
| Pseudo-traction electric displacement method (PTED) | p. 209 |
| Conservation law and consistency check | p. 214 |
| The mechanical strain energy release rate (MSERR) | p. 219 |
| Variable tendencies of the SIF owing to microcracking | p. 220 |
| Variable tendencies of the EDIF against the location angle | p. 224 |
| Variable tendencies of the mechanical strain energy release rate (MSERR) | p. 225 |
| Oriented microcrack | p. 229 |
| Brief Summary | p. 231 |
| Microcrack Damage in Piezoelectric Materials | p. 235 |
| General description of the present problem | p. 235 |
| J[subscript k] vector in piezoelectric media: physical interpretation and conservation laws | p. 237 |
| Path independence of the two components of the J[subscript k] vector | p. 237 |
| Conservation laws: statement | p. 238 |
| Mathematical proof of conservation laws | p. 239 |
| Numerical techniques and examples | p. 244 |
| Pseudo-traction electric displacement method | p. 246 |
| Numerical results | p. 249 |
| Applications: two arbitrarily located interacting cracks | p. 252 |
| Brief Summary | p. 256 |
| Some other Developments of the Conservation Laws and Energy Release Rates | p. 261 |
| Application of the M integral to the Zener crack | p. 262 |
| Conservation laws in functional materials | p. 266 |
| Energy Momentum Tensor in piezoelectric materials | p. 266 |
| Energy momentum tensor in functional materials | p. 269 |
| Bueckner's work conjugate integral in piezoelectric materials | p. 277 |
| Application of conservation laws of invariant integrals in nanostructures | p. 286 |
| Summary | p. 289 |
| Index | p. 297 |
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