Surface Engineering of ZrCuAl-based Bulk Metallic Glasses by Gaseous Oxidizing

Material Science

• Surface Engineering 100%
• Bulk Metallic Glass 100%
• Oxidation Reaction 60%
• Residual Stress 30%
• X-Ray Diffraction 20%
• Stress Relaxation 15%
• Focused Ion Beam 15%
• Shear Band 10%
• Crystalline Material 10%
• Zirconia 5%
• Glass Transition 5%
• Diffraction Measurement 5%
• Surface Crack 5%
• Microstructural Evolution 5%
• Yield Stress 5%
• Surface Hardening 5%
• Atomic Structure 5%
• Metal 5%
• Ultimate Tensile Strength 5%
• Thermogravimetric Analysis 5%
• Crack Initiation 5%
• Crack Formation 5%
• Nanocrystalline 5%
• Brittleness 5%
• Advanced Material 5%
• Oxide Compound 5%

Engineering

• Bulk Metallic Glass 100%
• Engineering 100%
• Compressive Residual Stress 25%
• Ray Diffraction 15%
• Surface Region 15%
• Stress Relaxation 15%
• Thermal Oxidation 10%
• Induced Oxidation 10%
• Residual Stress 5%
• Free Surface 5%
• Elevated Temperature 5%
• Response Surface 5%
• Atmospheric Condition 5%
• Induced Change 5%
• Plane Surface 5%
• Digital Image Correlation 5%
• Oxidation Zone 5%
• Tensile Stress σ 5%
• Comparable Result 5%
• Focused Ion Beam 5%
• Glass Surface 5%
• Elastic Limit 5%
• Ray Diffraction Technique 5%
• Microstructural Feature 5%
• High Oxygen Partial Pressure 5%
• Defects 5%
• Shear Band Formation 5%
• Crack Initiation 5%
• Crack Formation 5%
• Nanocrystalline 5%
• Shear Band 5%
• Surface Crack 5%
• Microstructural Evolution 5%
• Main Result 5%
• Brittleness 5%
• Yield Strength 5%
• Oxygen Atom 5%

Keyphrases

• Oxygen Dissolution 10%
• FIB-DIC 10%
• Self-repairing Mechanism 5%
• Metastable Solids 5%
• Oxygen Potential 5%
• Thermal Oxidation Behavior 5%
• In-situ Oxide 5%
• DIC Method 5%
• Image Correlation Technique 5%