Tribological behaviour and microscopic wear mechanisms of UHMWPE sliding against thermal oxidation-treated Ti6A14V

Keyphrases

• Thermal Oxidation 100%
• Tribological Behavior 100%
• Ultra-high Molecular Weight Polyethylene (UHMWPE) 100%
• Wear Mechanism 100%
• Ti-6A1-4V 100%
• Microscopic Wear 100%
• Microcracks 40%
• Fatigue Mechanism 40%
• Surface Material 20%
• Ti-6Al-4V Alloy 20%
• Counterface 20%
• Lubrication Condition 20%
• Water Lubrication 20%
• Stress-induced 20%
• Spallation 20%
• Wear Surface 20%
• Cyclic Loading 20%
• SEM Analysis 20%
• Wear Mode 20%
• High Resolution SEM 20%
• Wear Debris 20%
• Average Surface Roughness 20%
• Preferential Orientation 20%
• Rubbing 20%
• Fatigue Wear 20%
• Lateral Propagation 20%
• Crystalline Lamellae 20%

Engineering

• Thermal Oxidation 100%
• High Molecular Weight Polyethylene 100%
• Tribological Behavior 100%
• Microcracks 40%
• Micro Crack 40%
• Cross Section 20%
• High Resolution 20%
• Experimental Result 20%
• Counterface 20%
• Induced Stress 20%
• Surface Fatigue 20%
• Cyclic Loading 20%
• Wear Debris 20%
• Surface Material 20%
• Average Surface Roughness 20%
• Lateral Propagation 20%
• Interconnection 20%

Material Science

• Polyethylene 100%
• Microcracks 40%
• Surface (Surface Science) 20%
• Scanning Electron Microscopy 20%
• Surface Roughness 20%
• Lubrication 20%
• Surface Fatigue 20%
• Wear Debris 20%