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Observation of the nonlinear Hall effect under time-reversal-symmetric conditions

Author

Listed:
  • Qiong Ma

    (Massachusetts Institute of Technology)

  • Su-Yang Xu

    (Massachusetts Institute of Technology)

  • Huitao Shen

    (Massachusetts Institute of Technology)

  • David MacNeill

    (Massachusetts Institute of Technology)

  • Valla Fatemi

    (Massachusetts Institute of Technology)

  • Tay-Rong Chang

    (National Cheng Kung University)

  • Andrés M. Mier Valdivia

    (Massachusetts Institute of Technology)

  • Sanfeng Wu

    (Massachusetts Institute of Technology)

  • Zongzheng Du

    (Southern University of Science and Technology
    Shenzhen Key Laboratory of Quantum Science and Engineering
    Southeast University)

  • Chuang-Han Hsu

    (National University of Singapore
    National University of Singapore)

  • Shiang Fang

    (Harvard University)

  • Quinn D. Gibson

    (Princeton University)

  • Kenji Watanabe

    (National Institute for Materials Science)

  • Takashi Taniguchi

    (National Institute for Materials Science)

  • Robert J. Cava

    (Princeton University)

  • Efthimios Kaxiras

    (Harvard University
    Harvard University)

  • Hai-Zhou Lu

    (Southern University of Science and Technology
    Shenzhen Key Laboratory of Quantum Science and Engineering)

  • Hsin Lin

    (Academia Sinica)

  • Liang Fu

    (Massachusetts Institute of Technology)

  • Nuh Gedik

    (Massachusetts Institute of Technology)

  • Pablo Jarillo-Herrero

    (Massachusetts Institute of Technology)

Abstract

The electrical Hall effect is the production, upon the application of an electric field, of a transverse voltage under an out-of-plane magnetic field. Studies of the Hall effect have led to important breakthroughs, including the discoveries of Berry curvature and topological Chern invariants1,2. The internal magnetization of magnets means that the electrical Hall effect can occur in the absence of an external magnetic field2; this ‘anomalous’ Hall effect is important for the study of quantum magnets2–7. The electrical Hall effect has rarely been studied in non-magnetic materials without external magnetic fields, owing to the constraint of time-reversal symmetry. However, only in the linear response regime—when the Hall voltage is linearly proportional to the external electric field—does the Hall effect identically vanish as a result of time-reversal symmetry; the Hall effect in the nonlinear response regime is not subject to such symmetry constraints8–10. Here we report observations of the nonlinear Hall effect10 in electrical transport in bilayers of the non-magnetic quantum material WTe2 under time-reversal-symmetric conditions. We show that an electric current in bilayer WTe2 leads to a nonlinear Hall voltage in the absence of a magnetic field. The properties of this nonlinear Hall effect are distinct from those of the anomalous Hall effect in metals: the nonlinear Hall effect results in a quadratic, rather than linear, current–voltage characteristic and, in contrast to the anomalous Hall effect, the nonlinear Hall effect results in a much larger transverse than longitudinal voltage response, leading to a nonlinear Hall angle (the angle between the total voltage response and the applied electric field) of nearly 90 degrees. We further show that the nonlinear Hall effect provides a direct measure of the dipole moment10 of the Berry curvature, which arises from layer-polarized Dirac fermions in bilayer WTe2. Our results demonstrate a new type of Hall effect and provide a way of detecting Berry curvature in non-magnetic quantum materials.

Suggested Citation

  • Qiong Ma & Su-Yang Xu & Huitao Shen & David MacNeill & Valla Fatemi & Tay-Rong Chang & Andrés M. Mier Valdivia & Sanfeng Wu & Zongzheng Du & Chuang-Han Hsu & Shiang Fang & Quinn D. Gibson & Kenji Wata, 2019. "Observation of the nonlinear Hall effect under time-reversal-symmetric conditions," Nature, Nature, vol. 565(7739), pages 337-342, January.
  • Handle: RePEc:nat:nature:v:565:y:2019:i:7739:d:10.1038_s41586-018-0807-6
    DOI: 10.1038/s41586-018-0807-6
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    Citations

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    Cited by:

    1. Bin Cheng & Yang Gao & Zhi Zheng & Shuhang Chen & Zheng Liu & Ling Zhang & Qi Zhu & Hui Li & Lin Li & Changgan Zeng, 2024. "Giant nonlinear Hall and wireless rectification effects at room temperature in the elemental semiconductor tellurium," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    2. Ji-Eun Lee & Aifeng Wang & Shuzhang Chen & Minseong Kwon & Jinwoong Hwang & Minhyun Cho & Ki-Hoon Son & Dong-Soo Han & Jun Woo Choi & Young Duck Kim & Sung-Kwan Mo & Cedomir Petrovic & Choongyu Hwang , 2024. "Spin-orbit-splitting-driven nonlinear Hall effect in NbIrTe4," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    3. Feng-Ren Fan & Cong Xiao & Wang Yao, 2024. "Intrinsic dipole Hall effect in twisted MoTe2: magnetoelectricity and contact-free signatures of topological transitions," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    4. Zhongqiang Chen & Hongsong Qiu & Xinjuan Cheng & Jizhe Cui & Zuanming Jin & Da Tian & Xu Zhang & Kankan Xu & Ruxin Liu & Wei Niu & Liqi Zhou & Tianyu Qiu & Yequan Chen & Caihong Zhang & Xiaoxiang Xi &, 2024. "Defect-induced helicity dependent terahertz emission in Dirac semimetal PtTe2 thin films," Nature Communications, Nature, vol. 15(1), pages 1-11, December.
    5. Yuki M. Itahashi & Toshiya Ideue & Shintaro Hoshino & Chihiro Goto & Hiromasa Namiki & Takao Sasagawa & Yoshihiro Iwasa, 2022. "Giant second harmonic transport under time-reversal symmetry in a trigonal superconductor," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    6. Zeya Li & Junwei Huang & Ling Zhou & Zian Xu & Feng Qin & Peng Chen & Xiaojun Sun & Gan Liu & Chengqi Sui & Caiyu Qiu & Yangfan Lu & Huiyang Gou & Xiaoxiang Xi & Toshiya Ideue & Peizhe Tang & Yoshihir, 2023. "An anisotropic van der Waals dielectric for symmetry engineering in functionalized heterointerfaces," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    7. Longjun Xiang & Hao Jin & Jian Wang, 2024. "Quantifying the photocurrent fluctuation in quantum materials by shot noise," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    8. Teng Ma & Hao Chen & Kunihiro Yananose & Xin Zhou & Lin Wang & Runlai Li & Ziyu Zhu & Zhenyue Wu & Qing-Hua Xu & Jaejun Yu & Cheng Wei Qiu & Alessandro Stroppa & Kian Ping Loh, 2022. "Growth of bilayer MoTe2 single crystals with strong non-linear Hall effect," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    9. Xiu Fang Lu & Cheng-Ping Zhang & Naizhou Wang & Dan Zhao & Xin Zhou & Weibo Gao & Xian Hui Chen & K. T. Law & Kian Ping Loh, 2024. "Nonlinear transport and radio frequency rectification in BiTeBr at room temperature," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    10. Hui Li & Chengping Zhang & Chengjie Zhou & Chen Ma & Xiao Lei & Zijing Jin & Hongtao He & Baikui Li & Kam Tuen Law & Jiannong Wang, 2024. "Quantum geometry quadrupole-induced third-order nonlinear transport in antiferromagnetic topological insulator MnBi2Te4," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    11. Yudi Dai & Junlin Xiong & Yanfeng Ge & Bin Cheng & Lizheng Wang & Pengfei Wang & Zenglin Liu & Shengnan Yan & Cuiwei Zhang & Xianghan Xu & Youguo Shi & Sang-Wook Cheong & Cong Xiao & Shengyuan A. Yang, 2024. "Interfacial magnetic spin Hall effect in van der Waals Fe3GeTe2/MoTe2 heterostructure," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    12. Lujin Min & Hengxin Tan & Zhijian Xie & Leixin Miao & Ruoxi Zhang & Seng Huat Lee & Venkatraman Gopalan & Chao-Xing Liu & Nasim Alem & Binghai Yan & Zhiqiang Mao, 2023. "Strong room-temperature bulk nonlinear Hall effect in a spin-valley locked Dirac material," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    13. Lukas Powalla & Jonas Kiemle & Elio J. König & Andreas P. Schnyder & Johannes Knolle & Klaus Kern & Alexander Holleitner & Christoph Kastl & Marko Burghard, 2022. "Berry curvature-induced local spin polarisation in gated graphene/WTe2 heterostructures," Nature Communications, Nature, vol. 13(1), pages 1-8, December.

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