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| Editor's Preface on Fracture Mechanics | |
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| Editors Preface on Fatigue | |
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| List of Contributors | |
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| Airy Stress Function Method | |
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| Westergaard Method for a Crack Under Concentrated Forces | |
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| Westergaard Method for a Periodic Array of Cracks Under Concentrated Forces | |
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| Westergaard Method for a Periodic Array of Cracks Under Uniform Stress | |
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| Calculation of Stress Intensity Factors by the Westergaard Method | |
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| Westergaard Method for a Crack Under Distributed Forces | |
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| Westergaard Method for a Crack Under Concentrated Forces | |
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| Westergaard Method for a Crack Problem | |
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| Westergaard Method for a Crack Subjected to Shear Forces | |
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| Calculation of Stress Intensity Factors by Superposition | |
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| Calculation of Stress Intensity Factors by Integration | |
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| Stress Intensity Factors for a Linear Stress Distribution | |
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| Mixed-Mode Stress Intensity Factors in Cylindrical Shells | |
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| Photoelastic Determination of Stress Intensity Factors K[subscript I] | |
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| Photoelastic Determination of Mixed-Mode Stress Intensity Factors K[subscript I] and K[subscript II] | |
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| Application of the Method of Weight Function for the Determination of Stress Intensity Factors | |
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| Approximate Determination of the Crack Tip Plastic Zone for Mode-I and Mode-II Loading | |
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| Approximate Determination of the Crack Tip Plastic Zone for Mixed-Mode Loading | |
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| Approximate Determination of the Crack Tip Plastic Zone According to the Tresca Yield Criterion | |
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| Approximate Determination of the Crack Tip Plastic Zone According to a Pressure Modified Mises Yield Criterion | |
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| Crack Tip Plastic Zone According to Irwin's Model | |
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| Effective Stress Intensity factor According to Irwin's Model | |
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| Plastic Zone at the Tip of a Semi-Infinite Crack According to the Dugdale Model | |
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| Model-III Crack Tip Plastic Zone According to the Dugdale Model | |
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| Plastic Zone at the Tip of a Penny-Shaped Crack According to the Dugdale Model | |
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| Calculation of Strain Energy Release Rate from Load - Displacement - Crack Area Equation | |
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| Calculation of Strain Energy Release Rate for Deformation Modes I, II and III | |
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| Compliance of a Plate with a Central Crack | |
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| Strain Energy Release Rate for a Semi-Infinite Plate with a Crack | |
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| Strain Energy Release Rate for the Short Rod Specimen | |
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| Strain Energy Release Rate for the Blister Test | |
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| Calculation of Stress Intensity Factors Based on Strain Energy Release Rate | |
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| Critical Strain Energy Release Rate | |
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| Experimental Determination of Critical Stress Intensity Factor K[subscript Ic] | |
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| Experimental Determination of K[subscript Ic] | |
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| Crack Stability | |
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| Stable Crack Growth Based on the Resistance Curve Method | |
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| Three-Point Bending Test in Brittle Materials | |
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| Three-Point Bending Test in Quasi Brittle Materials | |
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| Double-Cantilever Beam Test in Brittle Materials | |
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| Design of a Pressure Vessel | |
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| Thermal Loads in a Pipe | |
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| J-integral for an Elastic Beam Partly Bonded to a Half-Plane | |
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| J-integral for a Strip with a Semi-Infinite Crack | |
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| J-integral for Two Partly Bonded Layers | |
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| J-Integral for Mode-I | |
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| J-integral for Mode III | |
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| Path Independent Integrals | |
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| Stress Around Notches | |
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| Experimental Determination of J[subscript Ic] from J - Crack Growth Curves | |
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| Experimental Determination of J from Potential Energy - Crack Length Curves | |
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| Experimental Determination of J from Load-Displacement Records | |
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| Experimental Determination of J from a Compact Tension Specimen | |
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| Validity of J[subscript Ic] and K[subscript Ic] Tests | |
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| Critical Crack Opening Displacement | |
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| Crack Opening Displacement Design Methodology | |
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| Critical Fracture Stress of a Plate with an Inclined Crack | |
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| Critical Crack Length of a Plate with an Inclined Crack | |
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| Failure of a Plate with an Inclined Crack | |
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| Growth of a Plate with an Inclined Crack Under Biaxial Stresses | |
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| Crack Growth Under Mode-II Loading | |
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| Growth of a Circular Crack Loaded Perpendicularly to its Cord by Tensile Stress | |
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| Growth of a Circular Crack Loaded Perpendicular to its Cord by Compressive Stress | |
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| Growth of a Circular Crack Loaded Parallel to its Cord | |
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| Growth of Radial Cracks Emanating from a Hole | |
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| Strain Energy Density in Cuspidal Points of Rigid Inclusions | |
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| Failure from Cuspidal Points of Rigid Inclusions | |
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| Failure of a Plate with a Hypocycloidal Inclusion | |
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| Crack Growth From Rigid Rectilinear Inclusions | |
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| Crack Growth Under Pure Shear | |
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| Critical Stress in Mixed Mode Fracture | |
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| Critical Stress for an Interface Crack | |
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| Failure of a Pressure Vessel with an Inclined Crack | |
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| Failure of a Cylindrical bar with a Circular Crack | |
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| Failure of a Pressure Vessel Containing a Crack with Inclined Edges | |
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| Failure of a Cylindrical Bar with a Ring-Shaped Edge Crack | |
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| Stable and Unstable Crack Growth | |
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| Dynamic Stress Intensity Factor | |
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| Crack Speed During Dynamic Crack Propagation | |
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| Rayleigh Wave Speed | |
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| Dilatational, Shear and Rayleigh Wave Speeds | |
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| Speed and Acceleration of Crack Propagation | |
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| Stress Enhanced Concentration of Hydrogen around Crack Tips | |
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| Subcritical Crack Growth due to the Presence of a Deleterious Species | |
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| Estimating the Lifetime of Aircraft Wing Stringers | |
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| Estimating Long Life Fatigue of Components | |
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| Strain Life Fatigue Estimation of Automotive Component | |
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| Lifetime Estimates Using LEFM | |
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| Lifetime of a Gas Pipe | |
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| Pipe Failure and Lifetime Using LEFM | |
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| Strain Life Fatigue Analysis of Automotive Suspension Component | |
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| Fatigue Crack Growth in a Center-Cracked Thin Aluminium Plate | |
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| Effect of Crack Size on Fatigue Life | |
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| Effect of Fatigue Crack Length on Failure Mode of a Center-Cracked Thin Aluminium Plate | |
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| Crack Propagation Under Combined Tension and Bending | |
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| Influence of Mean Stress on Fatigue Crack Growth for Thin and Thick Plates | |
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| Critical Fatigue Crack Growth in a Rotor Disk | |
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| Applicability of LEFM to Fatigue Crack Growth | |
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| Fatigue Crack Growth in the Presence of Residual Stress Field | |
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| Fatigue Crack Growth in a Plate Containing an Open Hole | |
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| Infinite Life for a Plate with a Semi-circular Notch | |
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| Infinite Life for a Plate with a Central Hole | |
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| Crack Initiation in a Sheet Containing a Central Hole | |
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| Inspection Scheduling | |
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| Safety Factor of a U-Notched Plate | |
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| Safety Factor and Fatigue Life Estimates | |
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| Design of a Circular Bar for Safe Life | |
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| Threshold and LEFM | |
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| Safety Factor and Residual Strength | |
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| Design of a Rotating Circular Shaft for Safe Life | |
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| Safety Factor of a Notched Member Containing a Central Crack | |
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| Safety Factor of a Disk Sander | |
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| Short Cracks and LEFM Error | |
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| Stress Ratio effect on the Kitagawa-Takahashi diagram | |
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| Susceptibility of Materials to Short Cracks | |
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| The effect of the Stress Ratio on the Propagation of Short Fatigue Cracks in 2024-T3 | |
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| Crack Growth Rate During Irregular Loading | |
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| Fatigue Life Under two-stage Block Loading | |
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| The Application of Wheeler's Model | |
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| Fatigue Life Under Multiple-Stage Block Loading | |
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| Fatigue Life Under two-stage Block Loading Using Non-Linear Damage Accumulation | |
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| Fatigue Crack Retardation Following a Single Overload | |
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| Fatigue Life of a Pipe Under Variable Internal Pressure | |
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| Fatigue Crack Growth Following a Single Overload Based on Crack Closure | |
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| Fatigue Crack Growth Following a Single Overload Based on Crack-Tip Plasticity | |
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| Fatigue Crack Growth and Residual Strength of a Double Edge Cracked Panel Under Irregular Fatigue Loading | |
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| Fatigue Crack Growth Rate Under Irregular Fatigue Loading | |
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| Fatigue Life of Pressure Vessel Under Variable Internal Pressure | |
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| Equibiaxial Low Cycle Fatigue | |
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| Mixed Mode Fatigue Crack Growth in a Center-Cracked Panel | |
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| Collapse Stress and the Dugdale's Model | |
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| Torsional Low Cycle Fatigue | |
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| Fatigue Life Assessment of a Plate Containing Multiple Cracks | |
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| Fatigue Crack Growth and Residual Strength in a Simple MSD Problem | |
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| Index | |