Experimental characterization and micromechanical modeling of superelastic response of a porous NiTi shape-memory alloy

Engineering

• Experimental Characterization 100%
• Shape Memory Alloy 100%
• Micromechanical Modeling 100%
• Martensite 83%
• Austenite 50%
• Energy Engineering 33%
• Gibbs Free Energy 33%
• Porosity 33%
• Memory Effect 33%
• Austenite Phase 33%
• High Strain Rate 16%
• Plastic Deformation 16%
• Driving Force 16%
• Defects 16%
• Nanoscale 16%
• Strain Rate 16%
• Resistive 16%
• Initial Temperature 16%
• Stress-Strain Relations 16%
• Model Prediction 16%
• Intermetallics 16%
• Potential Energy 16%
• Chemical Energy 16%
• Static Loading 16%
• Dynamic Test 16%
• Good Correlation 16%
• Spark Plasma Sintering 16%
• Rate Test 16%
• Quasistatic Test 16%
• Constant Temperature 16%
• Thermodynamic Force 16%
• Induced Stress 16%
• Energy Barrier 16%
• Pulse Shaping 16%
• Applied Stress 16%
• Martensite Transformation 16%
• Induced Martensitic Transformation 16%

Material Science

• Shape Memory Effect 100%
• Martensite 75%
• Austenite 62%
• Strain Rate 25%
• Plastic Deformation 12%
• Superelasticity 12%
• Titanium 12%
• Stress-Strain Relations 12%
• Intermetallics 12%
• Static Loading 12%
• Spark Plasma Sintering 12%