Author
Listed:
- Anyuan Gao
(Harvard University)
- Yu-Fei Liu
(Harvard University)
- Chaowei Hu
(University of California, Los Angeles)
- Jian-Xiang Qiu
(Harvard University)
- Christian Tzschaschel
(Harvard University)
- Barun Ghosh
(Indian Institute of Technology
Northeastern University)
- Sheng-Chin Ho
(Harvard University)
- Damien Bérubé
(Harvard University)
- Rui Chen
(Southern University of Science and Technology (SUSTech))
- Haipeng Sun
(Southern University of Science and Technology (SUSTech))
- Zhaowei Zhang
(Nanyang Technological University)
- Xin-Yue Zhang
(Boston College)
- Yu-Xuan Wang
(Boston College)
- Naizhou Wang
(Nanyang Technological University)
- Zumeng Huang
(Nanyang Technological University)
- Claudia Felser
(Max Planck Institute for Chemical Physics of Solids)
- Amit Agarwal
(Indian Institute of Technology)
- Thomas Ding
(Boston College)
- Hung-Ju Tien
(National Cheng Kung University)
- Austin Akey
(Harvard University)
- Jules Gardener
(Harvard University)
- Bahadur Singh
(Tata Institute of Fundamental Research)
- Kenji Watanabe
(National Institute for Materials Science)
- Takashi Taniguchi
(National Institute for Materials Science)
- Kenneth S. Burch
(Boston College)
- David C. Bell
(Harvard University
Harvard University)
- Brian B. Zhou
(Boston College)
- Weibo Gao
(Nanyang Technological University)
- Hai-Zhou Lu
(Southern University of Science and Technology (SUSTech))
- Arun Bansil
(Northeastern University)
- Hsin Lin
(Academia Sinica)
- Tay-Rong Chang
(National Cheng Kung University
Center for Quantum Frontiers of Research and Technology (QFort)
National Taiwan University)
- Liang Fu
(Massachusetts Institute of Technology)
- Qiong Ma
(Boston College)
- Ni Ni
(University of California, Los Angeles)
- Su-Yang Xu
(Harvard University)
Abstract
Whereas ferromagnets have been known and used for millennia, antiferromagnets were only discovered in the 1930s1. At large scale, because of the absence of global magnetization, antiferromagnets may seem to behave like any non-magnetic material. At the microscopic level, however, the opposite alignment of spins forms a rich internal structure. In topological antiferromagnets, this internal structure leads to the possibility that the property known as the Berry phase can acquire distinct spatial textures2,3. Here we study this possibility in an antiferromagnetic axion insulator—even-layered, two-dimensional MnBi2Te4—in which spatial degrees of freedom correspond to different layers. We observe a type of Hall effect—the layer Hall effect—in which electrons from the top and bottom layers spontaneously deflect in opposite directions. Specifically, under zero electric field, even-layered MnBi2Te4 shows no anomalous Hall effect. However, applying an electric field leads to the emergence of a large, layer-polarized anomalous Hall effect of about 0.5e2/h (where e is the electron charge and h is Planck’s constant). This layer Hall effect uncovers an unusual layer-locked Berry curvature, which serves to characterize the axion insulator state. Moreover, we find that the layer-locked Berry curvature can be manipulated by the axion field formed from the dot product of the electric and magnetic field vectors. Our results offer new pathways to detect and manipulate the internal spatial structure of fully compensated topological antiferromagnets4–9. The layer-locked Berry curvature represents a first step towards spatial engineering of the Berry phase through effects such as layer-specific moiré potential.
Suggested Citation
Anyuan Gao & Yu-Fei Liu & Chaowei Hu & Jian-Xiang Qiu & Christian Tzschaschel & Barun Ghosh & Sheng-Chin Ho & Damien Bérubé & Rui Chen & Haipeng Sun & Zhaowei Zhang & Xin-Yue Zhang & Yu-Xuan Wang & Na, 2021.
"Layer Hall effect in a 2D topological axion antiferromagnet,"
Nature, Nature, vol. 595(7868), pages 521-525, July.
Handle:
RePEc:nat:nature:v:595:y:2021:i:7868:d:10.1038_s41586-021-03679-w
DOI: 10.1038/s41586-021-03679-w
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Citations
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Cited by:
- Shuai Li & Ming Gong & Yu-Hang Li & Hua Jiang & X. C. Xie, 2024.
"High spin axion insulator,"
Nature Communications, Nature, vol. 15(1), pages 1-8, December.
- Dmitry Ovchinnikov & Jiaqi Cai & Zhong Lin & Zaiyao Fei & Zhaoyu Liu & Yong-Tao Cui & David H. Cobden & Jiun-Haw Chu & Cui-Zu Chang & Di Xiao & Jiaqiang Yan & Xiaodong Xu, 2022.
"Topological current divider in a Chern insulator junction,"
Nature Communications, Nature, vol. 13(1), pages 1-6, December.
- Junyeong Ahn & Su-Yang Xu & Ashvin Vishwanath, 2022.
"Theory of optical axion electrodynamics and application to the Kerr effect in topological antiferromagnets,"
Nature Communications, Nature, vol. 13(1), pages 1-17, December.
- Yaoxin Li & Yongchao Wang & Zichen Lian & Hao Li & Zhiting Gao & Liangcai Xu & Huan Wang & Rui’e Lu & Longfei Li & Yang Feng & Jinjiang Zhu & Liangyang Liu & Yongqian Wang & Bohan Fu & Shuai Yang & Lu, 2024.
"Fabrication-induced even-odd discrepancy of magnetotransport in few-layer MnBi2Te4,"
Nature Communications, Nature, vol. 15(1), pages 1-9, December.
- Kuan-Sen Lin & Giandomenico Palumbo & Zhaopeng Guo & Yoonseok Hwang & Jeremy Blackburn & Daniel P. Shoemaker & Fahad Mahmood & Zhijun Wang & Gregory A. Fiete & Benjamin J. Wieder & Barry Bradlyn, 2024.
"Spin-resolved topology and partial axion angles in three-dimensional insulators,"
Nature Communications, Nature, vol. 15(1), pages 1-17, December.
- Su Kong Chong & Chao Lei & Seng Huat Lee & Jan Jaroszynski & Zhiqiang Mao & Allan H. MacDonald & Kang L. Wang, 2023.
"Anomalous Landau quantization in intrinsic magnetic topological insulators,"
Nature Communications, Nature, vol. 14(1), pages 1-8, December.
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