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Numerical analysis of a model for ferromagnetic shape memory thin films
Mitchell Luskin
, Tianyu Zhang
School of Mathematics
Research output
:
Contribution to journal
›
Article
›
peer-review
7
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Scopus citations
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Keyphrases
Numerical Analysis
100%
Magnetization
100%
Ferromagnetic Shape Memory Alloys
100%
Convergence Rate
66%
Single Crystal
33%
Nonconvex
33%
Multiple Phases
33%
Finite Element Method
33%
Ni2MnGa
33%
Magnetic Energy
33%
Applied Magnetic Field
33%
Elastic Energy
33%
Reference Configuration
33%
Non-convex Energy
33%
Non-convexity
33%
Numerical Computation
33%
Saturation Condition
33%
Spatial Frame
33%
Multiple Symmetry
33%
Magnetic Saturation
33%
Mathematics
Numerical Analysis
100%
Shape Memory Effect
100%
Finite Element Methods
50%
Multiple Model
50%
Spatial Frame
50%
Magnetic Saturation
50%
Convergence Rate
50%
Numerical Computation
50%
Applied Magnetic Field
50%
Rate of Convergence
50%
Engineering
Thin Films
100%
Rate of Convergence
25%
Reference Configuration
25%
Convergence Rate
25%
Numerical Computation
25%
Elastic Energy
25%
Magnetic Energy
25%
Applied Magnetic Field
25%
Constant Magnitude
25%
Finite Element Analysis
25%
Crystal Structure
25%
Material Science
Shape Memory
100%
Thin Films
100%
Finite Element Methods
25%
Numerical Computational Method
25%
Single Crystal
25%
Crystal Structure
25%