Direct observation of distinct bulk and edge nonequilibrium spin accumulation in ultrathin MoTe2

Fangchu Chen; Kamal Das; Bowen Yang; Chuangtang Wang; Shazhou Zhong; Diana Golovanova; He Ren; Tianyang Wang; Xuan Luo; Yuping Sun; Liuyan Zhao; Guo-Xing Miao; Binghai Yan; Adam W. Tsen

doi:10.1038/s41467-025-61550-2

Direct observation of distinct bulk and edge nonequilibrium spin accumulation in ultrathin MoTe₂

Fangchu Chen, Kamal Das, Bowen Yang, Chuangtang Wang, Shazhou Zhong, Diana Golovanova, He Ren, Tianyang Wang, Xuan Luo, Yuping Sun, Liuyan Zhao, Guo-Xing Miao, Binghai Yan, Adam W. Tsen

Department of Condensed Matter Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Low-symmetry two-dimensional (2D) topological materials such as MoTe2 host efficient charge-to-spin conversion (CSC) mechanisms that can be harnessed for novel electronic and spintronic devices. However, the nature of the various CSC mechanisms and their correlation with underlying crystal symmetries remain unsettled. In this work, we use local spin-sensitive electrochemical potential measurements to directly probe the spatially dependent nonequilibrium spin accumulation in MoTe₂ flakes down to four atomic layers. We are able to clearly disentangle contributions originating from the spin Hall and Rashba-Edelstein effects and uncover an abundance of unconventional spin polarizations that develop uniquely in the sample bulk and edges with decreasing thickness. Using ab-initio calculations, we construct a unified understanding of all the observed CSC components in relation to the material dimensionality and stacking arrangement. Our findings not only illuminate previous CSC results on MoTe₂ but also have important ramifications for future devices that can exploit the local and layer-dependent spin properties of this 2D topological material.

Original language	English
Article number	6132
Number of pages	8
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-61550-2
Publication status	Published Online - 3 Jul 2025

Funding

We thank Prof. Ding Fu Shao at the Institute of Solid State Physics, Chinese Academy of Sciences for helpful discussions of our manuscript. A.W.T. acknowledges support from the Dorothy Killam Fellowship and US Air Force Office of Scientific Research (FA9550-24-1-0360). A.W.T. and G.-X.M. acknowledge support from the Natural Sciences and Engineering Research Council of Canada (NSERC) and the Transformative Quantum Technologies Program. B.Y. acknowledges the financial support by the Israel Science Foundation (ISF: 2932/21) and National Science Foundation through the Penn State Materials Research Science and Engineering Center (MRSEC) DMR 2011839. L.Z. acknowledges the support from the U.S. Department of Energy (DOE), Office of Science, Basic Energy Science (BES), under award No. DE-SC0024145. X.L. and Y.P.S. thank the support from the National Key R&D Program (Grant Nos. 2023YFA1607402, 2021YFA1600201), the National Natural Science Foundation of China (Grant Nos. U2032215, No. U1932217, and 12274412), and Systematic Fundamental Research Program Leveraging Major Scientific and Technological Infrastructure, Chinese Academy of Sciences under contract No. JZHKYPT-2021-08. K.D. acknowledges the financial support from Weizmann Institute of Science, Dean of Faculty fellowship and the Koshland Foundation.

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

Access to Document

10.1038/s41467-025-61550-2Licence: CC BY-NC-ND

Cite this

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title = "Direct observation of distinct bulk and edge nonequilibrium spin accumulation in ultrathin MoTe2",

abstract = "Low-symmetry two-dimensional (2D) topological materials such as MoTe2 host efficient charge-to-spin conversion (CSC) mechanisms that can be harnessed for novel electronic and spintronic devices. However, the nature of the various CSC mechanisms and their correlation with underlying crystal symmetries remain unsettled. In this work, we use local spin-sensitive electrochemical potential measurements to directly probe the spatially dependent nonequilibrium spin accumulation in MoTe2 flakes down to four atomic layers. We are able to clearly disentangle contributions originating from the spin Hall and Rashba-Edelstein effects and uncover an abundance of unconventional spin polarizations that develop uniquely in the sample bulk and edges with decreasing thickness. Using ab-initio calculations, we construct a unified understanding of all the observed CSC components in relation to the material dimensionality and stacking arrangement. Our findings not only illuminate previous CSC results on MoTe2 but also have important ramifications for future devices that can exploit the local and layer-dependent spin properties of this 2D topological material.",

author = "Fangchu Chen and Kamal Das and Bowen Yang and Chuangtang Wang and Shazhou Zhong and Diana Golovanova and He Ren and Tianyang Wang and Xuan Luo and Yuping Sun and Liuyan Zhao and Guo-Xing Miao and Binghai Yan and Tsen, \{Adam W.\}",

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AU - Chen, Fangchu

AU - Das, Kamal

AU - Yang, Bowen

AU - Wang, Chuangtang

AU - Zhong, Shazhou

AU - Golovanova, Diana

AU - Ren, He

AU - Wang, Tianyang

AU - Luo, Xuan

AU - Sun, Yuping

AU - Zhao, Liuyan

AU - Miao, Guo-Xing

AU - Yan, Binghai

AU - Tsen, Adam W.

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AB - Low-symmetry two-dimensional (2D) topological materials such as MoTe2 host efficient charge-to-spin conversion (CSC) mechanisms that can be harnessed for novel electronic and spintronic devices. However, the nature of the various CSC mechanisms and their correlation with underlying crystal symmetries remain unsettled. In this work, we use local spin-sensitive electrochemical potential measurements to directly probe the spatially dependent nonequilibrium spin accumulation in MoTe2 flakes down to four atomic layers. We are able to clearly disentangle contributions originating from the spin Hall and Rashba-Edelstein effects and uncover an abundance of unconventional spin polarizations that develop uniquely in the sample bulk and edges with decreasing thickness. Using ab-initio calculations, we construct a unified understanding of all the observed CSC components in relation to the material dimensionality and stacking arrangement. Our findings not only illuminate previous CSC results on MoTe2 but also have important ramifications for future devices that can exploit the local and layer-dependent spin properties of this 2D topological material.

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