Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material

De-Yang Wang; Qi jiang; Kenta Kuroda; Kaishu Kawaguchi; Ayumi Harasawa; Koichiro Yaji; Arthur Ernst; Hao-Ji Qian; Wen-Jing Liu; He-Ming Zha; Zhi-Cheng Jiang; Ni Ma; Hong-Ping Mei; Ang Li; Takeshi Kondo; Shan Qiao; Mao Ye

doi:10.1103/PhysRevLett.129.146401

Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material

De-Yang Wang
, Qi jiang
, Kenta Kuroda
, Kaishu Kawaguchi
, Ayumi Harasawa
, Koichiro Yaji
, Arthur Ernst
, Hao-Ji Qian
, Wen-Jing Liu
, He-Ming Zha
, Zhi-Cheng Jiang
, Ni Ma
, Hong-Ping Mei
, Ang Li
, Takeshi Kondo
, Shan Qiao
, Mao Ye

Department of Many Particle Systems

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

Abstract

Topological materials have broad application prospects in quantum computing and spintronic devices. Among them, dual topological materials with low dimensionality provide an excellent platform for manipulating various topological states and generating highly conductive spin currents. However, direct observation of their topological surface states still lacks. Here, we reveal the coexistence of the strong and weak topological phases in a quasi-one-dimensional material, TaNiTe5, by spin- and angle- resolved photoemission spectroscopy. The surface states protected by weak topological order forms Dirac-node arcs in the vicinity of the Fermi energy, providing the opportunity to develop spintronics devices with high carrier density that is tunable by bias voltage.

Original language	English
Article number	146401
Pages (from-to)	146401
Number of pages	6
Journal	Physical Review Letters
Volume	129
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevLett.129.146401
Publication status	Published - 30 Sept 2022

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103 Physics, Astronomy

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10.1103/PhysRevLett.129.146401

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Wang, D.-Y., jiang, Q., Kuroda, K., Kawaguchi, K., Harasawa, A., Yaji, K., Ernst, A., Qian, H.-J., Liu, W.-J., Zha, H.-M., Jiang, Z.-C., Ma, N., Mei, H.-P., Li, A., Kondo, T., Qiao, S., & Ye, M. (2022). Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material. Physical Review Letters, 129(14), 146401. Article 146401. https://doi.org/10.1103/PhysRevLett.129.146401

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title = "Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material",

abstract = "Topological materials have broad application prospects in quantum computing and spintronic devices. Among them, dual topological materials with low dimensionality provide an excellent platform for manipulating various topological states and generating highly conductive spin currents. However, direct observation of their topological surface states still lacks. Here, we reveal the coexistence of the strong and weak topological phases in a quasi-one-dimensional material, TaNiTe5, by spin- and angle- resolved photoemission spectroscopy. The surface states protected by weak topological order forms Dirac-node arcs in the vicinity of the Fermi energy, providing the opportunity to develop spintronics devices with high carrier density that is tunable by bias voltage.",

author = "De-Yang Wang and Qi jiang and Kenta Kuroda and Kaishu Kawaguchi and Ayumi Harasawa and Koichiro Yaji and Arthur Ernst and Hao-Ji Qian and Wen-Jing Liu and He-Ming Zha and Zhi-Cheng Jiang and Ni Ma and Hong-Ping Mei and Ang Li and Takeshi Kondo and Shan Qiao and Mao Ye",

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Wang, D-Y, jiang, Q, Kuroda, K, Kawaguchi, K, Harasawa, A, Yaji, K, Ernst, A, Qian, H-J, Liu, W-J, Zha, H-M, Jiang, Z-C, Ma, N, Mei, H-P, Li, A, Kondo, T, Qiao, S & Ye, M 2022, 'Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material', Physical Review Letters, vol. 129, no. 14, 146401, pp. 146401. https://doi.org/10.1103/PhysRevLett.129.146401

TY - JOUR

T1 - Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material

AU - Wang, De-Yang

AU - jiang, Qi

AU - Kuroda, Kenta

AU - Kawaguchi, Kaishu

AU - Harasawa, Ayumi

AU - Yaji, Koichiro

AU - Ernst, Arthur

AU - Qian, Hao-Ji

AU - Liu, Wen-Jing

AU - Zha, He-Ming

AU - Jiang, Zhi-Cheng

AU - Ma, Ni

AU - Mei, Hong-Ping

AU - Li, Ang

AU - Kondo, Takeshi

AU - Qiao, Shan

AU - Ye, Mao

PY - 2022/9/30

Y1 - 2022/9/30

N2 - Topological materials have broad application prospects in quantum computing and spintronic devices. Among them, dual topological materials with low dimensionality provide an excellent platform for manipulating various topological states and generating highly conductive spin currents. However, direct observation of their topological surface states still lacks. Here, we reveal the coexistence of the strong and weak topological phases in a quasi-one-dimensional material, TaNiTe5, by spin- and angle- resolved photoemission spectroscopy. The surface states protected by weak topological order forms Dirac-node arcs in the vicinity of the Fermi energy, providing the opportunity to develop spintronics devices with high carrier density that is tunable by bias voltage.

AB - Topological materials have broad application prospects in quantum computing and spintronic devices. Among them, dual topological materials with low dimensionality provide an excellent platform for manipulating various topological states and generating highly conductive spin currents. However, direct observation of their topological surface states still lacks. Here, we reveal the coexistence of the strong and weak topological phases in a quasi-one-dimensional material, TaNiTe5, by spin- and angle- resolved photoemission spectroscopy. The surface states protected by weak topological order forms Dirac-node arcs in the vicinity of the Fermi energy, providing the opportunity to develop spintronics devices with high carrier density that is tunable by bias voltage.

UR - https://www.scopus.com/pages/publications/85139858294

U2 - 10.1103/PhysRevLett.129.146401

DO - 10.1103/PhysRevLett.129.146401

M3 - Article

SN - 1079-7114

VL - 129

SP - 146401

JO - Physical Review Letters

JF - Physical Review Letters

IS - 14

M1 - 146401

ER -

Coexistence of Strong and Weak Topological Orders in a Quasi-One-Dimensional Material

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