Temperature-Dependent Viscoelastic Energy Dissipation and Fatigue Crack Growth in Filled Silicone Elastomers

Keyphrases

• Energy Dissipation 100%
• Temperature Effect 100%
• Silicone Elastomer 100%
• Power Law 100%
• Fatigue Crack Growth 100%
• Elastomer 66%
• Mechanical Properties 33%
• Elevated Temperature 33%
• Natural Rubber 33%
• Fatigue Resistance 33%
• Material Behavior 33%
• Large Amplitude 33%
• Large Strain 33%
• Filled Rubber 33%
• Silicone Rubber 33%
• Fracture Behavior 33%
• Fatigue Crack Propagation 33%
• Small Strain 33%
• Rough Cracks 33%
• Viscoelastic Behavior 33%
• Cyclic Deformation 33%
• Fatigue Test 33%
• Dynamic Mechanical Analysis 33%
• Phase Angle 33%
• Mechanical Fracture 33%
• Material Toughness 33%
• Stored Elastic Energy 33%
• Crack Morphology 33%
• Crack Propagation Resistance 33%
• Growth per Cycle 33%
• Pure Shear Mode 33%
• Rubber Elastomers 33%
• Viscoelastic Dissipation 33%
• Filled Silicone Rubber 33%

Engineering

• Energy Dissipation 100%
• Fatigue Crack Growth 100%
• Elastomer 100%
• Fatigue Crack Propagation 25%
• Driving Force 25%
• Pure Shear 25%
• Fatigue Resistance 25%
• Elevated Temperature 25%
• Mechanical Fatigue Test 25%
• Crack Propagation 25%
• Fracture Behavior 25%
• Stored Elastic Energy 25%
• Power Law Exponent 25%
• Temperature Dependency 25%
• Filled Rubber 25%
• Phase Shift 25%
• Dynamic Mechanical Analysis 25%

Material Science

• Polysiloxane 100%
• Fatigue Crack Growth 100%
• Elastomer 100%
• Crack Propagation 50%
• Fracture Behavior 25%
• Fatigue of Materials 25%
• Viscoelastic Behavior 25%
• Fatigue Crack 25%
• Dynamic Mechanical Analysis 25%