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Size effects on magnetic actuation in Ni-Mn-Ga shape-memory alloys
David C. Dunand
, Peter Müllner
Materials Science and Engineering
Research output
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Contribution to journal
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Article
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peer-review
328
Scopus citations
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Keyphrases
Shape Memory Alloy
100%
Size Effect
100%
Ni-Mn-Ga
100%
Magnetic-field-induced Strain
100%
Magnetic Actuation
100%
Large Magnetic Field
50%
Bamboo
33%
Strut Diameter
33%
Magnetic Field
16%
Textile
16%
Microstructure
16%
Free Space
16%
Near-zero
16%
Grain Size
16%
Particle Size
16%
Ribbon
16%
Fiber Diameter
16%
Film Thickness
16%
Wire Diameter
16%
Macrostructure
16%
Thin Plate
16%
Geometric Constraints
16%
Off-stoichiometry
16%
Twin Boundary
16%
Internal Stress
16%
Plate Thickness
16%
Magnetic Shape Memory Alloys
16%
Monocrystalline
16%
Fiber Ribbon
16%
Polycrystal
16%
Grain Width
16%
Small Dimension
16%
Magneto-mechanical Properties
16%
Magnetocrystalline Anisotropy
16%
Fiber Film
16%
Ni-Mn-Sn Heusler Alloys
16%
Geometric Effect
16%
Material Science
Shape Memory Effect
100%
Anisotropy
100%
Magnetic Shape Memory Alloy
100%
Grain Size
100%
Film Thickness
100%
Film
100%
Polycrystal
100%