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A Lumped Energy Model for Crack Growth in Shape-Memory Materials
Perry H. Leo
, Thomas W. Shield
Aerospace Engineering and Mechanics
Research output
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Article
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peer-review
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Keyphrases
Shape Memory Alloy
100%
Crack Growth
100%
Shape Memory Materials
100%
Crack Length
100%
Energy Model
100%
Martensite Volume Fraction
100%
Stress-induced
50%
Single Crystal
50%
Total Energy
50%
Martensite
50%
Crack Tip
50%
Surface Energy
50%
Austenite
50%
Elastic Energy
50%
Crack Growth Behavior
50%
Polycrystal
50%
Stable Crack Growth
50%
Austenite-to-martensite Phase Transformation
50%
Loading Device
50%
Transformation Criteria
50%
Unstable Growth
50%
Equilibrium Cracks
50%
Material Science
Crack Growth
100%
Martensite
100%
Shape Memory
100%
Shape Memory Effect
50%
Volume Fraction
50%
Austenite
50%
Crack Tip
25%
Surface Energy
25%
Stable Crack Growth
25%
Polycrystal
25%
Single Crystal
25%