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二维材料中由贝里曲率诱导的新型磁学响应是近年来的新兴领域. 这些二维材料所表现出的磁学特性及量子输运与贝里曲率直接相关, 而贝里曲率又与晶体的对称性、电子的轨道磁性、自旋轨道耦合以及磁电效应等息息相关. 研究这些新型磁性响应一方面有益于研究不同量子效应间的耦合作用, 另一方面可探索量子效应在电子与信息器件领域的应用. 本文介绍了近几年来二维材料中新型磁响应的实验研究进展, 特别介绍了二硫化钼和石墨烯等材料中的谷霍尔和磁电效应、低对称性的二碲化钨等材料中的量子非线性霍尔以及转角石墨烯中的反常霍尔和量子反常霍尔效应. 本文结合二维材料的晶体结构以及电子结构, 介绍了这些新奇现象的现有物理解释、回顾了相关研究的最新发展、讨论了其中尚未理解的现象, 并作出展望.The magnetic response in a two-dimensional material has received increasing attention in recent years. The magnetic effects and related quantum transport originate from Berry curvature, which is associated with crystal symmetry and many quantum effects including electrons’ orbital magnetism, spin-orbit coupling, and magnetoelectricity. The importance of studying the magnetic response in the two-dimensional material lies in two aspects. First, the magnetic response of two-dimensional material provides a platform to investigate the coupling between the above-mentioned intrinsic quantum effects and their couplings. Second, it possesses the potential applications in energy-efficient quantum and spintronic devices. Here, we review the experimental research progress made in recent years. In particular, we focus on the research progress of the valley Hall and magnetoelectric effect, quantum non-linear Hall effect, anomalous Hall, and quantum anomalous Hall effect in two-dimensional materials such as graphene, transition-metal chalcogenides, and twisted bilayer graphene. For each session, we first introduce these phenomena and their underlying physics by using crystal symmetries and band structures. Then, we summarize the experimental results and identify unsolved problems. At last, we provide an outlook in this emerging research direction.
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Keywords:
- two-dimensional material /
- orbital magnetism /
- quantum effects /
- Berry curvature
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图 1 受应力的单层硫化钼谷磁电效应示意图 (a)谷霍尔效应[22]; (b)谷磁电效应[25]; (c)自旋极化引起的磁矩和谷磁电性引起的磁矩在外磁场下的磁光克尔响应; (d)磁光克尔响应与施加电流方向和应力方向的关系
Fig. 1. Sketch of the magnetoelectric effect in monolayer MoS2: (a) Valley Hall effect[22]; (b) valley magnetoelectricity[25]; (c) comparison of magneto-optical Kerr response between spin polarizations induced magnetism and valley magnetization under external magnetic fields; (d) valley magnetization-induced Kerr rotation as a function of the azimuthal angle of current for zigzag and armchair monolayer MoS2.
图 2 碲化钨中量子非线性霍尔效应示意图 (a)线性和非线性霍尔电压随电流的变化[47]; (b)碲化钨在不同方向上的晶体结构示意图; (c)纵向电压和非线性霍尔电压与电流施加方向的关系[27]; (d)非线性霍尔电压与材料电导率的关系. 插图表示了非线性霍尔效应的两种来源: 贝里曲率和电子偏散射输运[27]
Fig. 2. Illustration of the quantum nonlinear Hall effect: (a) Dependence of linear and non-linear Hall voltage on applied currents[47]; (b) crystal structure of WTe2; (c) angular dependence of longitudinal voltage and non-linear Hall voltage[27]; (d) relationship between nonlinear Hall voltage and conductance. The inset shows two origins of nonlinear Hall voltage: Intrinsic Berry curvature and skew scattering[27].
图 3 转角双层石墨烯中量子反常霍尔效应示意图 (a)自旋磁化和轨道磁化中量子反常霍尔效应对比示意图; (b)转角双层石墨烯中自旋极化和能谷非极化的导带示意图; (c)转角双层石墨烯中自旋和能谷完全极化的导带示意图; (d)量子反常霍尔态下, 霍尔电阻和纵向电阻随磁场的变化关系, 插图表示材料的导电状态—边缘导电和体导电; (e)电流控制反常霍尔态下磁性翻转示意图
Fig. 3. Illustration of quantum anomalous Hall effect in twisted bilayer graphene (tBLG): (a) Sketch of quantum anomalous Hall effect in spin magnetization and orbital magnetization systems; (b) schematic of fully spin-polarized and but valley-unpolarized conduction bands in a moiré unit cell of tBLG; (c) schematic of fully spin-polarized and valley-polarized conduction bands in a moiré unit cell of tBLG; (d) longitudinal resistance and Hall resistance as a function of magnetic field in the quantum anomalous Hall state, and the insets show the bulk and edge conduction states of material; (e) current control of magnetization switching in the anomalous Hall state.
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