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Layer Hall effect in a 2D topological Axion antiferromagnet

Authors :
Gao, Anyuan
Liu, Yu-Fei
Hu, Chaowei
Qiu, Jian-Xiang
Tzschaschel, Christian
Ghosh, Barun
Ho, Sheng-Chin
Bérubé, Damien
Chen, Rui
Sun, Haipeng
Zhang, Zhaowei
Zhang, Xin-Yue
Wang, Yu-Xuan
Wang, Naizhou
Huang, Zumeng
Felser, Claudia
Agarwal, Amit
Ding, Thomas
Tien, Hung-Ju
Akey, Austin
Gardener, Jules
Singh, Bahadur
Watanabe, Kenji
Taniguchi, Takashi
Burch, Kenneth S.
Bell, David C.
Zhou, Brian B.
Gao, Weibo
Lu, Hai-Zhou
Bansil, Arun
Lin, Hsin
Chang, Tay-Rong
Fu, Liang
Ma, Qiong
Ni, Ni
Xu, Su-Yang
Publication Year :
2021

Abstract

While ferromagnets have been known and exploited for millennia, antiferromagnets (AFMs) were only discovered in the 1930s. The elusive nature indicates AFMs' unique properties: At large scale, due to the absence of global magnetization, AFMs may appear to behave like any non-magnetic material; However, such a seemingly mundane macroscopic magnetic property is highly nontrivial at microscopic level, where opposite spin alignment within the AFM unit cell forms a rich internal structure. In topological AFMs, such an internal structure leads to a new possibility, where topology and Berry phase can acquire distinct spatial textures. Here, we study this exciting possibility in an AFM Axion insulator, even-layered MnBi$_2$Te$_4$ flakes, where spatial degrees of freedom correspond to different layers. Remarkably, we report the observation of a new type of Hall effect, the layer Hall effect, where electrons from the top and bottom layers spontaneously deflect in opposite directions. Specifically, under no net electric field, even-layered MnBi$_2$Te$_4$ shows no anomalous Hall effect (AHE); However, applying an electric field isolates the response from one layer and leads to the surprising emergence of a large layer-polarized AHE (~50%$\frac{e^2}{h}$). Such a layer Hall effect uncovers a highly rare layer-locked Berry curvature, which serves as a unique character of the space-time $\mathcal{PT}$-symmetric AFM topological insulator state. Moreover, we found that the layer-locked Berry curvature can be manipulated by the Axion field, E$\cdot$B, which drives the system between the opposite AFM states. Our results achieve previously unavailable pathways to detect and manipulate the rich internal spatial structure of fully-compensated topological AFMs. The layer-locked Berry curvature represents a first step towards spatial engineering of Berry phase, such as through layer-specific moir\'e potential.<br />Comment: A revised version of this article is published in Nature

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.2107.10233
Document Type :
Working Paper
Full Text :
https://doi.org/10.1038/s41586-021-03679-w