Enhancing fatigue performance of austenitic stainless steel via warm surface severe plastic deformation using surface mechanical attrition treatment

Engineering

• Austenitic Stainless Steel 100%
• Compressive Residual Stress 66%
• Endurance Limit 100%
• Fatigue Behavior 33%
• Fatigue Crack 33%
• Fatigue Limit 66%
• Fatigue Performance 100%
• Fatigue Property 33%
• Mechanical Fatigue Test 33%
• Nucleation Site 33%
• Plastic Deformation 100%
• Residual Stress 33%
• Room Temperature 100%
• Shot Peening 66%
• Stress Condition 33%
• Stress Gradient 33%
• Stress Raiser 33%
• Subsurface 66%
• Tensiles 33%

Keyphrases

• 316L Austenitic Stainless Steel 16%
• Austenitic Stainless Steel 100%
• Beneficial Role 16%
• Compressive Residual Stress 33%
• Crack nucleation 16%
• Endurance Limit 50%
• Extreme Surfaces 16%
• Fatigue Behavior 16%
• Fatigue Crack 16%
• Fatigue Limit 33%
• Fatigue Performance 100%
• Fatigue Properties 16%
• Microstructure 16%
• Microstructure Hardness 16%
• Nucleation Site 16%
• Nucleation Surface 16%
• Peening 33%
• Residual Stress Gradient 16%
• Room Temperature 50%
• Rotating Bending Fatigue Test 16%
• Shot Impact 16%
• Stress Conditions 16%
• Stress Raiser 16%
• Surface Crack 16%
• Surface Mechanical Attrition Treatment 100%
• Surface nucleation 16%
• Surface Oxidation 16%
• Surface Severe Plastic Deformation 100%
• Surface Stress 16%

Material Science

• Austenitic Stainless Steel 100%
• Fatigue Behavior 20%
• Fatigue Crack 20%
• Machining 20%
• Nucleation 80%
• Plastic Deformation 100%
• Residual Stress 60%
• Surface (Surface Science) 100%
• Surface Stress 20%