Structural Evolution and Mechanisms of Fatigue in Polycrystalline Brass

Engineering

• Plastic Strain 100%
• Controlled Fatigue 100%
• Polycrystalline 100%
• Stress-Strain Curve 66%
• Fatigue Life 66%
• Life Curve 66%
• Cyclic Stress 66%
• Austenitic Stainless Steel 66%
• Range Order 66%
• Model System 33%
• Fatigue Damage 33%
• Model Type 33%
• Crack Face 33%
• Polycrystal 33%
• Softening Behavior 33%
• Growth Behavior 33%
• Individual Grain 33%
• Structural Behavior 33%
• Damage Evolution 33%
• Fatigue Behavior 33%
• Shear Band 33%

Material Science

• Fatigue of Materials 100%
• Short-Range Order 100%
• Shear Band 50%
• Austenitic Stainless Steel 50%
• Structural Behavior 50%
• Damage Evolution 50%
• Fatigue Damage 50%
• Zinc 50%
• Fatigue Behavior 50%
• Austenitic Stainless Steels 50%
• Polycrystal 50%

Keyphrases

• Fatigue Life Curve 28%
• Slip Mode 14%
• Hardening-softening 14%
• Surface Observations 14%
• Extended Dipoles 14%
• Intergranular Damage 14%
• Wavy Slip 14%
• Eshelby Model 14%
• Secondary Hardening 14%
• 316L Austenitic Stainless Steel 14%