Coupling between martensitic phase transformations and plasticity: A microstructure-based finite element model

International Journal of Plasticity

Volumn 26, Issue 10, 2010, Pages 1508-1526

  Manchiraju, S ^a   Anderson, P M ^a  

^a The Ohio State University   (United States)

Author keywords

Plasticity; Pseudoelasticity; Shape memory alloys; Thermal cycling; Two way effect

Indexed keywords

APPLIED STRESS; CRYSTALLOGRAPHIC LEVEL; DEFORMATION PROCESSING; DETWINNING; DRIVING FORCES; ELEVATED TEMPERATURE; FINITE ELEMENT; FINITE ELEMENT MODELS; IMPOSED STRAINS; MARTENSITE VOLUME FRACTION; MARTENSITIC PHASE TRANSFORMATIONS; MICRO-STRUCTURAL; NITI SHAPE MEMORY ALLOYS; PHASE TRANSFORMATION; PSEUDOELASTIC; PSEUDOELASTIC RESPONSE; PSEUDOELASTICITY; SHAPE MEMORY ALLOY; SHAPE MEMORY BEHAVIOR; TWO-WAY EFFECT; UNIQUE FEATURES;

ELASTICITY; FINITE ELEMENT METHOD; INTERMETALLICS; MARTENSITE; MARTENSITIC TRANSFORMATIONS; PLASTICITY; SHAPE MEMORY EFFECT; STRAIN; THERMAL CYCLING; UNLOADING;

SINGLE CRYSTALS;

EID: 77956610758     PISSN: 07496419     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijplas.2010.01.009     Document Type: Article

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