Influence of atomic ordering on elastocaloric and magnetocaloric effects of a Ni–Cu–Mn–Ga ferromagnetic shape memory alloy

•Ni51Cu4Mn20Ga25 alloy exhibits normal elastocaloric and magnetocaloric effects.•L21 atomic order of the alloy is increased after annealing at 773K for 10h.•Increasing L21 atomic order improves its elastocaloric and magnetocaloric effects.•Atomic ordering modifies the magnetic and martensitic transi...

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Bibliographic Details
Published in:Journal of alloys and compounds 2015-05, Vol.630, p.244-249
Main Authors: Huang, Chonghui, Wang, Yu, Tang, Zhao, Liao, Xiaoqi, Yang, Sen, Song, Xiaoping
Format: Article
Language:English
Subjects:
Alloys
Atomic ordering
Elastocaloric effect
Entropy
Ferromagnetic shape memory alloy
Ferromagnetism
Magnetocaloric effect
Martensitic transformations
Martensitic transition
Nickel
Order disorder
Refrigeration
Shape memory alloys
Solid state
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Summary:•Ni51Cu4Mn20Ga25 alloy exhibits normal elastocaloric and magnetocaloric effects.•L21 atomic order of the alloy is increased after annealing at 773K for 10h.•Increasing L21 atomic order improves its elastocaloric and magnetocaloric effects.•Atomic ordering modifies the magnetic and martensitic transitions of the system. The coexisting elastocaloric and magnetocaloric effects in ferromagnetic shape memory alloys have attracted much attention for the potential application in solid state refrigeration. Previous studies show that the L21 atomic ordering of Heusler ferromagnetic shape memory alloys plays important role on their magnetocaloric effect. However, no research work investigates the effect of atomic ordering on their elastocaloric effect yet. In this study, we investigated the influence of atomic ordering on the elastocaloric and magnetocaloric effects of a Ni51Cu4Mn20Ga25 ferromagnetic shape memory alloy. The alloy exhibits normal elastocaloric effect and normal magnetocaloric effect near room temperature. Moreover, we found that the enhancement of atomic order in this alloy can greatly increase the entropy change and refrigeration capacity of its elastocaloric and magnetocaloric effects. This is attributed to that the atomic ordering modifies the magnetic and martensitic transitions of the system.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2015.01.040