Strength reduction of unidirectional composites using micromechanical damage analysis of scanned microstructure

Engineering

• Damage Evolution 100%
• Damage Analysis 100%
• Macroscale 50%
• Experimental Result 50%
• Great Importance 50%
• Stress-Strain Relations 50%
• Stress Concentration 50%
• Microscale 50%
• Effective Property 50%
• Material System 50%
• Repeating Unit 50%
• Micromechanical Model 50%
• Generalized Method 50%
• Method of Cell 50%
• Direct Effect 50%
• Square Array 50%
• Global Response 50%
• Epoxy Material 50%
• Composite Material 50%

Keyphrases

• Microstructure 100%
• Strength Reduction 100%
• Unidirectional Composites 100%
• Damage Analysis 100%
• Micromechanical Damage 100%
• Scanning Electron Microscopy 28%
• Lamin 28%
• Damage Evolution 28%
• Stiffness 14%
• Imperfection 14%
• Global-local 14%
• Stress Concentration 14%
• Composite Materials 14%
• Mechanical Properties 14%
• Optical Methods 14%
• Challenging Tasks 14%
• Waviness 14%
• Effective Properties 14%
• Strength Prediction 14%
• Hexagonal Array 14%
• Material System 14%
• Micromechanical Modeling 14%
• Repeating Unit Cell 14%
• High-fidelity Generalized Method of Cells 14%
• Composite Microstructure 14%
• Shear Loading 14%
• Micromechanical Method 14%
• Stress-strain Response 14%
• Transverse Loading 14%
• Interlaminar 14%
• Carbon Epoxy 14%
• Square Array 14%
• Fiber Distribution 14%
• Global Response 14%
• Global Damage 14%
• Epoxy Materials 14%
• Resin Pocket 14%

Material Science

• Composite Material 100%
• Scanning Electron Microscopy 22%
• Damage Evolution 22%
• Composite Material 11%
• Stress Concentration 11%
• Stress-Strain Relations 11%