The role of plasticity in bimaterial fracture with ductile interlayers

Keyphrases

• Bi-material 100%
• Interfacial Fracture Toughness 100%
• Plastic Energy Dissipation 66%
• Yield Stress 66%
• Energy Dissipation Rate 66%
• Plasticity Effect 66%
• Indentation Test 33%
• Nanoindentation 33%
• First-order 33%
• Experimental Values 33%
• Film Thickness 33%
• Tungsten 33%
• Large Strain 33%
• Small Strain 33%
• Crack Tip 33%
• Crack Extension 33%
• Cu Film 33%
• Flow Stress 33%
• Interfacial Fracture Energy 33%
• Interfacial Crack 33%
• Appropriate Model 33%
• Strain Energy Release Rate 33%
• Mode Mixing 33%
• Order Estimation 33%
• Constitutive Properties 33%
• Crack Tip Plasticity 33%
• Thick Cu 33%
• External Measures 33%
• Elastic-plastic Boundary 33%
• Cu-SiO2 33%
• Plastic Dissipation 33%
• Plastic Strain Energy Density 33%
• Cu Interlayer 33%
• Field Yield 33%

Engineering

• Energy Dissipation Rate 100%
• Plasticity Effect 100%
• Interlayer 100%
• Crack Tip 100%
• Yield Point 100%
• Experimental Value 50%
• Axisymmetric 50%
• Flow Stress 50%
• Indentation 50%
• Interfacial Fracture Energy 50%
• Mode Mixity 50%
• Interfacial Crack 50%
• Strain-Energy Release Rate 50%
• Crack Extension 50%
• Strain Energy Density 50%
• Elastic-plastic Boundary 50%
• Plastic Dissipation 50%
• Cu Film 50%
• Plastic Strain Energy 50%
• Silicon Dioxide 50%

Material Science

• Crack Tip 100%
• Film 100%
• Yield Stress 100%
• Nanoindentation 50%
• Silicon 50%
• Film Thickness 50%
• Tungsten 50%
• Energy Density 50%
• Indentation Hardness Testing 50%