Recent Development in Magnetic Shape Memory Alloys

doi:10.3390/books978-3-0365-6763-1

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Recent Development in Magnetic Shape Memory Alloys

Edited by

March 2023

166 pages

ISBN978-3-0365-6762-4 (Hardback)
ISBN978-3-0365-6763-1 (PDF)

https://doi.org/10.3390/books978-3-0365-6763-1

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This book is a reprint of the Special Issue Recent Development in Magnetic Shape Memory Alloys that was published in

Chemistry & Materials Science

Engineering

Summary

Heusler type magnetic shape memory alloys (MSMAs) have gained a strong academic and practical importance during recent decades due to the giant effects they exhibit, particularly magnetostrain produced by magnetic field-induced twin boundaries motion and magneto(elasto)-caloric effects resulting from the magnetic field-induced martensitic transformation.

This Special Issue intends to communicate the latest advances in R&D and theory of MSMAs. This book consists of a collection of eleven invited peer-reviewed papers, each detailing a particular aspect in the fundamental and/or applied investigation of MSMAs and related phenomena. The papers are a corpus of up-to-date information on the ongoing studies of MSMAs. It is hoped that this reprint will be useful to physicists and materials scientists, both specialists and graduate students, and enable future technological breakthroughs in engineering.

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Keywords

metamagnetic shape memory alloy; microwire; superelasticity; martensitic transformation; magnetocaloric effect; magnetic-field-induced phase transformation; magnetostructural transformation; shape memory effect; Ni-Mn-Ga; FSMA; electromagnetic coupling; smart materials; actuator; magnetic shape memory alloys; neutron scattering; Heusler alloys; Ni-Mn-Ga; doping; ferromagnetism; transition metals; Heusler alloy; martensitic transformation; superelastic effect; stress-induced stabilization of martensite; critical stress; Young’s modulus; Heusler alloys; ternary diagrams; structural phase stability; first-principles approach; magnetic shape memory alloys; twinning; a/c twins; a/b twin laminate; domain engineering; internal friction; Young’s modulus; Heusler alloys; martensitic transformation; neutron diffraction; magnetocrystalline anisotropy; magnetic shape memory alloys; Ni-Mn-Ga; Ni-Fe-Ga magnetic shape memory alloys; elastocaloric and magnetocaloric effects; martensitic transformation; spark plasma sintering; additive manufacturing; ferromagnetic; neutron diffraction; microstructure; nanoindentation; sintering