Anomalous Hall effect from nonlinear magnetoelectric coupling

arXiv - PHYS - Mesoscale and Nanoscale Physics Pub Date : 2024-09-18 DOI:arxiv-2409.11662

Longju Yu, Hong Jian Zhao, Yurong Yang, Laurent Bellaiche, Yanming Ma

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Abstract

The anomalous Hall effect (AHE) is a topology-related transport phenomenon being of potential interest in spintronics, because this effect enables the efficient probe of magnetic orders (i.e., data readout in memory devices). It is well known that AHE spontaneously occurs in ferromagnets or antiferromagnets with magnetization. While recent studies reveal electric-field induced AHE (via linear magnetoelectric coupling), an AHE originating from nonlinear magnetoelectric coupling remains largely unexplored. Here, by symmetry analysis, we establish the phenomenological theory regarding the spontaneous and electric-field driven AHE in magnets. We show that a large variety of magnetic point groups host an AHE that is driven by uni-axial, bi-axial, or tri-axial electric field and that comes from nonlinear magnetoelectric coupling. Such electric-field driven anomalous Hall conductivities are reversible by reversing the magnetic orders. Furthermore, our first-principles calculations suggest Cr2O3 and CoF2 as candidates hosting the aforementioned AHE. Our work emphasizes the important role of nonlinear magnetoelectric coupling in creating exotic transport phenomena, and offers alternative avenues for the probe of magnetic orders.

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非线性磁电耦合产生的反常霍尔效应

反常霍尔效应（AHE）是一种与拓扑相关的传输现象，在自旋电子学中具有潜在的意义，因为这种效应可以有效地探测磁序（即存储器件中的数据读出）。众所周知，AHE 会自发地发生在铁磁体或具有磁性的反铁磁体中。虽然最近的研究揭示了电场诱导的 AHE（线性磁电耦合），但源于非线性磁电耦合的 AHE 在很大程度上仍未被探索。在此，我们通过对称性分析，建立了有关磁体中自发和电场驱动 AHE 的现象学理论。我们的研究表明，在单轴、双轴或三轴电场的驱动下，大量磁性点群都会产生由非线性磁电耦合产生的反常现象。这种电场驱动的反常霍尔电导率可通过逆转磁序而逆转。此外，我们的第一性原理计算表明，Cr2O3 和 CoF2 可作为承载上述反常霍尔电导的候选物质。我们的工作强调了非线性磁电耦合在产生奇异输运现象中的重要作用，并为探测磁序提供了另一种途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Mesoscale and Nanoscale Physics

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