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Main Authors: Meng, Qingkai, Dong, Jianting, Nie, Pan, Xu, Liangcai, Wang, Jinhua, Jiang, Shan, Zuo, Huakun, Zhang, Jia, Li, Xiaokang, Zhu, Zengwei, Balents, Leon, Behnia, Kamran
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2301.06401
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author Meng, Qingkai
Dong, Jianting
Nie, Pan
Xu, Liangcai
Wang, Jinhua
Jiang, Shan
Zuo, Huakun
Zhang, Jia
Li, Xiaokang
Zhu, Zengwei
Balents, Leon
Behnia, Kamran
author_facet Meng, Qingkai
Dong, Jianting
Nie, Pan
Xu, Liangcai
Wang, Jinhua
Jiang, Shan
Zuo, Huakun
Zhang, Jia
Li, Xiaokang
Zhu, Zengwei
Balents, Leon
Behnia, Kamran
contents Whenever the elastic energy of a solid depends on magnetic field, there is a magnetostrictive response. Field-linear magnetostriction implies piezomagnetism and vice versa. Here, we show that Mn$_3$Sn, a non-collinear antiferromanget with Weyl nodes, hosts a large and almost perfectly linear magnetostriction even at room temperature. The longitudinal and transverse magnetostriction, with opposite signs and similar amplitude are restricted to the kagome planes and the out-of-plane response is negligibly small. By studying four different samples with different Mn:Sn ratios, we find a clear correlation between the linear magnetostriction, the spontaneous magnetization and the concentration of Sn vacancies. The recently reported piezomagnetic data fits in our picture. We show that linear magnetostriction and piezomagnetism are both driven by the field-induced in-plane twist of spins. A quantitative account of the experimental data requires the distortion of the spin texture by Sn vacancies. We find that the field-induced domain nucleation within the hysteresis loop corresponds to a phase transition. Within the hysteresis loop, a concomitant mesoscopic modulation of local strain and spin twist angles, leading to twisto-magnetic stripes, arises as a result of the competition between elastic and magnetic energies.
format Preprint
id arxiv_https___arxiv_org_abs_2301_06401
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Magnetostriction, piezomagnetism and domain nucleation in a kagome antiferromagnet
Meng, Qingkai
Dong, Jianting
Nie, Pan
Xu, Liangcai
Wang, Jinhua
Jiang, Shan
Zuo, Huakun
Zhang, Jia
Li, Xiaokang
Zhu, Zengwei
Balents, Leon
Behnia, Kamran
Strongly Correlated Electrons
Whenever the elastic energy of a solid depends on magnetic field, there is a magnetostrictive response. Field-linear magnetostriction implies piezomagnetism and vice versa. Here, we show that Mn$_3$Sn, a non-collinear antiferromanget with Weyl nodes, hosts a large and almost perfectly linear magnetostriction even at room temperature. The longitudinal and transverse magnetostriction, with opposite signs and similar amplitude are restricted to the kagome planes and the out-of-plane response is negligibly small. By studying four different samples with different Mn:Sn ratios, we find a clear correlation between the linear magnetostriction, the spontaneous magnetization and the concentration of Sn vacancies. The recently reported piezomagnetic data fits in our picture. We show that linear magnetostriction and piezomagnetism are both driven by the field-induced in-plane twist of spins. A quantitative account of the experimental data requires the distortion of the spin texture by Sn vacancies. We find that the field-induced domain nucleation within the hysteresis loop corresponds to a phase transition. Within the hysteresis loop, a concomitant mesoscopic modulation of local strain and spin twist angles, leading to twisto-magnetic stripes, arises as a result of the competition between elastic and magnetic energies.
title Magnetostriction, piezomagnetism and domain nucleation in a kagome antiferromagnet
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2301.06401