Current‐Induced Spin and Orbital Polarization in Magnetic Sliding Ferroelectrics

IF 2.5 4区物理与天体物理 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Physica Status Solidi-Rapid Research Letters Pub Date : 2024-04-22 DOI:10.1002/pssr.202400062

Haoxiang Dong, Jian Zhou

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Abstract

One of the main challenges for modern information read and write technology is how to effectively and precisely modulate the interconversion between electricity and magnetism with a high data density. Herein, it is proposed that two‐dimensional magnetic sliding ferroelectrics can serve as a prototypical material platform with tunable electric current‐induced magnetization variation, a typical nonequilibrium magnetoelectric coupling process. Using a CrI3 bilayer as the exemplary material, first‐principles calculations are performed to enumerate the monopole values, toroidal vectors, and quadrupole moment tensors. Their switching is also elucidated under a short distance sliding between the two layers, which can effectively flip the electric dipole moment. In addition to spin polarization which is usually studied for magnetic systems, the orbital moment contribution to the magnetoelectric coupling is also evaluated. They are found to be comparable in their magnitude and neither should be omitted, as opposed to equilibrium states. The work helps to reveal the underlining mechanisms among electronics, spintronics, and orbitronics in low‐dimensional multiferroic materials.

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磁性滑动铁电中电流诱导的自旋和轨道极化

现代信息读写技术面临的主要挑战之一是如何在高数据密度下有效、精确地调节电与磁之间的相互转换。本文提出，二维磁性滑动铁电体可作为具有可调电流诱导磁化变化（一种典型的非平衡磁电耦合过程）的原型材料平台。以 CrI3 双层材料为例，第一原理计算列举了单极值、环形矢量和四极矩张量。此外，还阐明了在两层之间短距离滑动的情况下它们的切换，这可以有效地翻转电偶极矩。除了通常研究磁性系统的自旋极化外，还评估了轨道力矩对磁电耦合的贡献。结果发现，与平衡态相比，它们的大小相当，都不应该被忽略。这项研究有助于揭示低维多铁性材料中电子学、自旋电子学和轨道电子学之间的基本机制。

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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来源期刊

Physica Status Solidi-Rapid Research Letters 物理-材料科学：综合

CiteScore

5.20

自引率

3.60%

发文量

208

审稿时长

1.4 months

期刊介绍： Physica status solidi (RRL) - Rapid Research Letters was designed to offer extremely fast publication times and is currently one of the fastest double peer-reviewed publication media in solid state and materials physics. Average times are 11 days from submission to first editorial decision, and 12 days from acceptance to online publication. It communicates important findings with a high degree of novelty and need for express publication, as well as other results of immediate interest to the solid-state physics and materials science community. Published Letters require approval by at least two independent reviewers. The journal covers topics such as preparation, structure and simulation of advanced materials, theoretical and experimental investigations of the atomistic and electronic structure, optical, magnetic, superconducting, ferroelectric and other properties of solids, nanostructures and low-dimensional systems as well as device applications. Rapid Research Letters particularly invites papers from interdisciplinary and emerging new areas of research.