External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire

External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire

Metamagnetic shape memory alloys exhibit a series of intriguing multifunctional properties and have great potential for applications in magnetic actuation, sensing and magnetic refrigeration. However, the poor mechanical properties of these alloys with hardly any tensile deformability seriously limi...

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Main Authors: Zhen Chen, Daoyong Cong, Shilei Li, Yin Zhang, Shaohui Li, Yuxian Cao, Shengwei Li, Chao Song, Yang Ren, Yandong Wang
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Metals
Subjects:
metamagnetic shape memory alloy
microwire
superelasticity
martensitic transformation
magnetocaloric effect
magnetic-field-induced phase transformation
Online Access:https://www.mdpi.com/2075-4701/11/2/309
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spelling doaj-aea832b5dee84938be465e53e1fad51a2021-02-11T00:05:40ZengMDPI AGMetals2075-47012021-02-011130930910.3390/met11020309External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory WireZhen Chen0Daoyong Cong1Shilei Li2Yin Zhang3Shaohui Li4Yuxian Cao5Shengwei Li6Chao Song7Yang Ren8Yandong Wang9Beijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaBeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaX-ray Science Division, Argonne National Laboratory, Argonne, IL 60439, USABeijing Advanced Innovation Center for Materials Genome Engineering, State Key Laboratory for Advanced Metals and Materials, University of Science and Technology Beijing, Beijing 100083, ChinaMetamagnetic shape memory alloys exhibit a series of intriguing multifunctional properties and have great potential for applications in magnetic actuation, sensing and magnetic refrigeration. However, the poor mechanical properties of these alloys with hardly any tensile deformability seriously limit their practical application. In the present work, we developed a Ni-Fe-Mn-In microwire that exhibits both a giant, tensile superelasticity and a magnetic-field-induced first-order phase transformation. The recoverable strain of superelasticity is more than 20% in the temperature range of 233–283 K, which is the highest recoverable strain reported heretofore in Ni-Mn-based shape memory alloys (SMAs). Moreover, the present microwire exhibits a large shape memory effect with a recoverable strain of up to 13.9% under the constant tensile stress of 225 MPa. As a result of the magnetic-field-induced first-order phase transformation, a large reversible magnetocaloric effect with an isothermal entropy change Δ<i>S</i><sub>m</sub> of 15.1 J kg<sup>−1</sup> K<sup>−1</sup> for a field change from 0.2 T to 5 T was achieved in this microwire. The realization of both magnetic-field and tensile-stress-induced transformations confers on this microwire great potential for application in miniature multi-functional devices and provides an opportunity for multi-functional property optimization under coupled multiple fields.https://www.mdpi.com/2075-4701/11/2/309metamagnetic shape memory alloymicrowiresuperelasticitymartensitic transformationmagnetocaloric effectmagnetic-field-induced phase transformation
collection DOAJ
language English
format Article
sources DOAJ
author Zhen Chen
Daoyong Cong
Shilei Li
Yin Zhang
Shaohui Li
Yuxian Cao
Shengwei Li
Chao Song
Yang Ren
Yandong Wang
spellingShingle Zhen Chen
Daoyong Cong
Shilei Li
Yin Zhang
Shaohui Li
Yuxian Cao
Shengwei Li
Chao Song
Yang Ren
Yandong Wang
External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire
Metals
metamagnetic shape memory alloy
microwire
superelasticity
martensitic transformation
magnetocaloric effect
magnetic-field-induced phase transformation
author_facet Zhen Chen
Daoyong Cong
Shilei Li
Yin Zhang
Shaohui Li
Yuxian Cao
Shengwei Li
Chao Song
Yang Ren
Yandong Wang
author_sort Zhen Chen
title External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire
title_short External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire
title_full External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire
title_fullStr External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire
title_full_unstemmed External-Field-Induced Phase Transformation and Associated Properties in a Ni<sub>50</sub>Mn<sub>34</sub>Fe<sub>3</sub>In<sub>13</sub> Metamagnetic Shape Memory Wire
title_sort external-field-induced phase transformation and associated properties in a ni<sub>50</sub>mn<sub>34</sub>fe<sub>3</sub>in<sub>13</sub> metamagnetic shape memory wire
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2021-02-01
description Metamagnetic shape memory alloys exhibit a series of intriguing multifunctional properties and have great potential for applications in magnetic actuation, sensing and magnetic refrigeration. However, the poor mechanical properties of these alloys with hardly any tensile deformability seriously limit their practical application. In the present work, we developed a Ni-Fe-Mn-In microwire that exhibits both a giant, tensile superelasticity and a magnetic-field-induced first-order phase transformation. The recoverable strain of superelasticity is more than 20% in the temperature range of 233–283 K, which is the highest recoverable strain reported heretofore in Ni-Mn-based shape memory alloys (SMAs). Moreover, the present microwire exhibits a large shape memory effect with a recoverable strain of up to 13.9% under the constant tensile stress of 225 MPa. As a result of the magnetic-field-induced first-order phase transformation, a large reversible magnetocaloric effect with an isothermal entropy change Δ<i>S</i><sub>m</sub> of 15.1 J kg<sup>−1</sup> K<sup>−1</sup> for a field change from 0.2 T to 5 T was achieved in this microwire. The realization of both magnetic-field and tensile-stress-induced transformations confers on this microwire great potential for application in miniature multi-functional devices and provides an opportunity for multi-functional property optimization under coupled multiple fields.
topic metamagnetic shape memory alloy
microwire
superelasticity
martensitic transformation
magnetocaloric effect
magnetic-field-induced phase transformation
url https://www.mdpi.com/2075-4701/11/2/309
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