Numerical Investigation of Interface Debonding of Particle Reinforced Composites by Unit Cell Model

Keyphrases

• Metal Matrix Composites 100%
• Particle-reinforced Composites 100%
• Interface Debonding 100%
• Numerical Investigation 100%
• Unit Cell Model 100%
• Cubic Model 75%
• Multi-particle 50%
• Matrix Materials 25%
• Fatigue Resistance 25%
• Elastic Sphere 25%
• Interfacial Damage 25%
• Maximum Normal Stress 25%
• Plastic Strain 25%
• Damage Evolution 25%
• Representative Unit Cell 25%
• Interfacial Strength 25%
• Randomly Distributed 25%
• Thermomechanical Behavior 25%
• Mechanical Properties of Metals 25%
• Interfacial Region 25%
• Inhomogeneous Structure 25%
• Periodic Unit Cell 25%
• High Specific Strength 25%
• Perfect Bonding 25%
• Tolerance Capability 25%
• Traditional Materials 25%
• Damage Tolerance 25%
• Stress Criterion 25%
• High Specific Stiffness 25%

Engineering

• Cell Model 100%
• Metal Matrix Composite 100%
• Debonding 100%
• Composite Material 100%
• Experimental Result 25%
• Simulated Result 25%
• Fatigue Resistance 25%
• Interfacial Damage 25%
• Plastic Strain 25%
• Representative Cell 25%
• Good Strength 25%
• Interfacial Region 25%
• Damage Evolution 25%
• Damage Tolerance 25%
• Matrix Material 25%

Material Science

• Debonding 100%
• Particle Reinforced Composites 100%
• Metal Matrix Composite 100%
• Composite Material 100%
• Fatigue of Materials 25%
• Composite Material 25%
• Damage Evolution 25%
• Damage Tolerance 25%