物理学进展

物理学进展 ›› 2026, Vol. 46 ›› Issue (2): 51-71.doi: 10.13725/j.cnki.pip.2026.02.00`

所属专题: 2026年, 第46卷

• •    下一篇

层状过渡金属化合物的磁性研究进展

徐 杰 ,张亚玲 ,刘晓璇 ,王媛媛 ,薛婷元 ,谷 亮 ,满潇潇,张会生 †   

  1. 山西师范大学物理与电子工程学院 , 磁性分子与磁信息材料教育部重点实验室, 山西师范大学材料科学研究院 , 太原 030006 
  • 收稿日期:2025-10-31 修回日期:2025-11-08 接受日期:2025-11-15 出版日期:2026-04-20 发布日期:2026-04-27
  • 基金资助:
    国家重点研发计划(项目编号:2024YFB3817400)、国家自然科学基金(项目编号:12274276、U24A6002)、山西省自然科学基金(项目编号:202403021223008),以及山西省高等学校科技创新项目(项目编号:2024Q017、2025L043)

Recent advances in the magnetism of layered transition-metal compounds

XU Jie , ZHANG Yaling , LIU Xiaoxuan , WANG Yuanyuan , XUE Tingyuan , GU Liang , MAN Xiaoxiao , ZHANG Huisheng †    

  1. College of Physics and Electronic Engineering, Key Laboratory of Magnetic Molecules and Magnetic Information Materials of the Ministry of Education, and Research Institute of Materials Science, Shanxi Normal University, Taiyuan 030006, China
  • Received:2025-10-31 Revised:2025-11-08 Accepted:2025-11-15 Online:2026-04-20 Published:2026-04-27
  • Supported by:
    National Key R&D Program of China (Grant No. 2024YFB3817400), the National Natural Science Foundation of China (Grants No. 12274276 and No. U24A6002), the Natural Science Foundation of Shanxi Province (China) (Grant No. 202403021223008), and Supported by Scientific and Technology Innovation Programs of Higher Education Institutions in Shanxi (Grant No. 2024Q017 and No. 2025L043).

PDF (PC)

58

摘要:

层状过渡金属化合物(LTMCs)凭借其层状结构、强磁各向异性和可调控的磁有序,为后 摩尔时代低功耗自旋电子器件和拓扑量子计算提供了理想材料平台。本文系统综述了 LTMCs 在 二维磁性研究中的最新进展,重点关注其材料体系分类、本征磁性质及多种外场调控策略。文章 首先依据晶体结构与化学组分,将 LTMCs 划分为二元卤化物、硫属化物及三元体系(如 MPX3、 MmXnTek 和 MnBi2Te4 家族),系统总结其磁耦合机制、有序温度及维度效应;进而详细探讨 电场调控、应变工程和离子插层等手段对磁交换作用、磁各向异性和拓扑物态的调制机理与实验 实现。近年来该领域涌现多项突破,如室温铁磁金属与半导体的实现、MnBi2Te4 中量子反常霍尔 效应的观测,以及多场耦合下磁–拓扑态的协同控制。然而,高居里温度本征二维磁性半导体仍较 稀缺,微观耦合机制与器件级稳定性仍是关键挑战。未来研究需结合多尺度表征、第一性原理计 算与跨尺度制备技术,实现磁性–拓扑–电子的精准调控,推动 LTMCs 在新型自旋器件和拓扑量 子计算中的应用。

关键词: 层状过渡金属化合物, 二维磁性, 电场调控, 应变工程, 离子插层, 拓扑磁性, 量子反 常霍尔效应

Abstract:

Layered transition-metal compounds (LTMCs) feature stacked architectures, strong magnetic anisotropy, and tunable magnetic order, making them promising material platforms for low-power spintronic technologies and for enabling topological functionalities in the post-Moore era. Here we review recent progress on two-dimensional (2D) magnetism in LTMCs, emphasizing material taxonomy, intrinsic magnetic properties, and external-field controls. This review first presents a classification of LTMCs by crystal structure and chemistry —binary halides, chalcogenides, and ternary families (e.g., MPX3, MmXnTek, MnBi2Te4) —followed by a summary of their coupling mechanisms, ordering temperatures, and dimensional effects. It then analyzes the modulation of exchange interactions, magnetic anisotropy, and topological states by electric-field gating, strain engineering, and ion intercalation, with representative experimental demonstrations. Notable advances include room-temperature ferromagnetic metals and semiconductors, observation of the quantum anomalous Hall effect (QAHE) in MnBi2Te4, and synergistic control of magnetic-topological states under multiple external stimuli. Persistent challenges involve the limited availability of intrinsic 2D magnetic semiconductors with high Curie temperatures (TC), incomplete understanding of the microscopic couplings at interfaces and under quantum confinement, and device-level stability. We conclude by outlining opportunities that lie in the integration of multiscale characterization, first-principles theory, and cross-scale fabrication to precisely co-engineer magnetism, topology, and electronic structure, thereby advancing LTMCs toward spintronic and topological-quantum applications

Key words:  , layered transition-metal compounds, two-dimensional magnetism, electric-field control, strain engineering, ion intercalation, topological magnetism, quantum anomalous Hall effec

中图分类号: