Magnetization dependent anisotropic topological properties in EuCuP

IF 3.1 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Physical Review Materials Pub Date : 2024-09-19 DOI:10.1103/physrevmaterials.8.094202
Jian Yuan, Xianbiao Shi, Hong Du, Wei Xia, Xia Wang, Jinguang Cheng, Baotian Wang, Ruidan Zhong, Shihao Zhang, Yanfeng Guo
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Abstract

The correlation between magnetism and nontrivial topological band structure serves as a unique venue for discovering exotic topological properties. Combining magnetotransport measurements and first-principles calculations, we unveil herein that the hexagonal EuCuP holds a topologically trivial state in the paramagnetic structure, while strong magnetization dependent anisotropic topological states in the spin-polarization structures. Specifically, it hosts a trivial topological state in the in-plane spin-polarization structure, while a Weyl semimetal state in the out-of-plane spin-polarization structure. Our scaling analysis suggests that the intrinsic Berry curvature in the spin-polarization structures can account for the observed large anisotropic anomalous Hall effect. First-principles calculations show that the magnetization and the spin-orbit coupling simultaneously play essential roles for the appearance of the four pairs of Weyl points in the out-of-plane spin-polarization structure. Our work therefore establishes in EuCuP the intimate relation between magnetism and the nontrivial topological states, which would be instructive for future study on this key issue of topological physics.

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EuCuP 中与磁化有关的各向异性拓扑特性
磁性与非琐碎拓扑带状结构之间的相关性是发现奇异拓扑特性的独特途径。结合磁传输测量和第一原理计算,我们在此揭示了六方 EuCuP 在顺磁结构中具有拓扑琐碎态,而在自旋极化结构中具有强磁化依赖的各向异性拓扑态。具体来说,它在面内自旋极化结构中具有拓扑三要态,而在面外自旋极化结构中具有韦尔半金属态。我们的缩放分析表明,自旋极化结构中的内在贝里曲率可以解释观察到的巨大各向异性反常霍尔效应。第一原理计算表明,磁化和自旋轨道耦合同时对平面外自旋极化结构中出现四对韦尔点起着至关重要的作用。因此,我们的工作在 EuCuP 中建立了磁性与非奇异拓扑态之间的密切关系,这对今后研究拓扑物理的这一关键问题具有指导意义。
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来源期刊
Physical Review Materials
Physical Review Materials Physics and Astronomy-Physics and Astronomy (miscellaneous)
CiteScore
5.80
自引率
5.90%
发文量
611
期刊介绍: Physical Review Materials is a new broad-scope international journal for the multidisciplinary community engaged in research on materials. It is intended to fill a gap in the family of existing Physical Review journals that publish materials research. This field has grown rapidly in recent years and is increasingly being carried out in a way that transcends conventional subject boundaries. The journal was created to provide a common publication and reference source to the expanding community of physicists, materials scientists, chemists, engineers, and researchers in related disciplines that carry out high-quality original research in materials. It will share the same commitment to the high quality expected of all APS publications.
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