A phase-field model of phase transitions and domain structures of NiCoMnIn metamagnetic alloys

H. B. Huang; X. Q. Ma; J. J. Wang; Z. H. Liu; W. Q. He; L. Q. Chen

doi:10.1016/j.actamat.2014.10.014

A phase-field model of phase transitions and domain structures of NiCoMnIn metamagnetic alloys

H. B. Huang, X. Q. Ma, J. J. Wang, Z. H. Liu, W. Q. He, L. Q. Chen

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30 Scopus citations

Abstract

We developed a computational model to investigate the magnetic and structural phase transitions in metamagnetic shape memory alloys. The model combined the phase-field method with micromagnetic simulations. The model was used to calculate the transition temperature from ferromagnetic austenite to antiferromagnetic martensite, the Curie temperature, and their response to an external magnetic field, for the typical metamagnetic alloy NiCoMnIn. The calculated magnetization curves at different temperatures are consistent with reported experimental measurements. The simulations show that the walls of martensite twins are superimposed with the 90° magnetic domain walls of the low-temperature martensite phase, because of magnetostructural order parameter coupling.

Original language	English (US)
Pages (from-to)	333-340
Number of pages	8
Journal	Acta Materialia
Volume	83
DOIs	https://doi.org/10.1016/j.actamat.2014.10.014
State	Published - Jan 15 2015

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Ceramics and Composites
Polymers and Plastics
Metals and Alloys

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10.1016/j.actamat.2014.10.014

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abstract = "We developed a computational model to investigate the magnetic and structural phase transitions in metamagnetic shape memory alloys. The model combined the phase-field method with micromagnetic simulations. The model was used to calculate the transition temperature from ferromagnetic austenite to antiferromagnetic martensite, the Curie temperature, and their response to an external magnetic field, for the typical metamagnetic alloy NiCoMnIn. The calculated magnetization curves at different temperatures are consistent with reported experimental measurements. The simulations show that the walls of martensite twins are superimposed with the 90° magnetic domain walls of the low-temperature martensite phase, because of magnetostructural order parameter coupling.",

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AU - Huang, H. B.

AU - Ma, X. Q.

AU - Wang, J. J.

AU - Liu, Z. H.

AU - He, W. Q.

AU - Chen, L. Q.

PY - 2015/1/15

Y1 - 2015/1/15

N2 - We developed a computational model to investigate the magnetic and structural phase transitions in metamagnetic shape memory alloys. The model combined the phase-field method with micromagnetic simulations. The model was used to calculate the transition temperature from ferromagnetic austenite to antiferromagnetic martensite, the Curie temperature, and their response to an external magnetic field, for the typical metamagnetic alloy NiCoMnIn. The calculated magnetization curves at different temperatures are consistent with reported experimental measurements. The simulations show that the walls of martensite twins are superimposed with the 90° magnetic domain walls of the low-temperature martensite phase, because of magnetostructural order parameter coupling.

AB - We developed a computational model to investigate the magnetic and structural phase transitions in metamagnetic shape memory alloys. The model combined the phase-field method with micromagnetic simulations. The model was used to calculate the transition temperature from ferromagnetic austenite to antiferromagnetic martensite, the Curie temperature, and their response to an external magnetic field, for the typical metamagnetic alloy NiCoMnIn. The calculated magnetization curves at different temperatures are consistent with reported experimental measurements. The simulations show that the walls of martensite twins are superimposed with the 90° magnetic domain walls of the low-temperature martensite phase, because of magnetostructural order parameter coupling.

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JO - Acta Materialia

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A phase-field model of phase transitions and domain structures of NiCoMnIn metamagnetic alloys

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