Discovery of a Single-Band Mott Insulator in a van der Waals Flat-Band Compound

Shunye Gao; Shuai Zhang; Cuixiang Wang; Shaohua Yan; Xin Han; Xuecong Ji; Wei Tao; Jingtong Liu; Tiantian Wang; Shuaikang Yuan; Gexing Qu; Ziyan Chen; Yongzhao Zhang; Jierui Huang; Mojun Pan; Shiyu Peng; Yong Hu; Hang Li; Yaobo Huang; Hui Zhou; Sheng Meng; Liu Yang; Zhiwei Wang; Yugui Yao; Zhiguo Chen; Ming Shi; Hong Ding; Huaixin Yang; Kun Jiang; Yunliang Li; Hechang Lei; Youguo Shi; Hongming Weng; Tian Qian

doi:10.1103/PhysRevX.13.041049

Discovery of a Single-Band Mott Insulator in a van der Waals Flat-Band Compound

Shunye Gao, Shuai Zhang, Cuixiang Wang, Shaohua Yan, Xin Han, Xuecong Ji, Wei Tao, Jingtong Liu, Tiantian Wang, Shuaikang Yuan, Gexing Qu, Ziyan Chen, Yongzhao Zhang, Jierui Huang, Mojun Pan, Shiyu Peng, Yong Hu, Hang Li, Yaobo Huang, Hui ZhouSheng Meng, Liu Yang, Zhiwei Wang, Yugui Yao, Zhiguo Chen, Ming Shi, Hong Ding, Huaixin Yang, Kun Jiang, Yunliang Li, Hechang Lei^*, Youguo Shi^*, Hongming Weng^*, Tian Qian^*

^*Corresponding author for this work

School of Physics

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

15 Citations (Scopus)

Abstract

The Mott insulator provides an excellent foundation for exploring a wide range of strongly correlated physical phenomena, such as high-temperature superconductivity, quantum spin liquid, and colossal magnetoresistance. A Mott insulator with the simplest degree of freedom is an ideal and highly desirable system for studying the fundamental physics of Mottness. In this study, we have unambiguously identified such an anticipated Mott insulator in a van der Waals layered compound Nb3Cl8. In the high-temperature phase, where interlayer coupling is negligible, density functional theory calculations for the monolayer of Nb3Cl8 suggest a half-filled flat band at the Fermi level, whereas angle-resolved photoemission spectroscopy experiments observe a large gap. This observation is perfectly reproduced by dynamical mean-field theory calculations considering strong electron correlations, indicating a correlation-driven Mott insulator state. Since this half-filled band derived from a single 2a1 orbital is isolated from all other bands, the monolayer of Nb3Cl8 is an ideal realization of the celebrated single-band Hubbard model. Upon decreasing the temperature, the bulk system undergoes a phase transition, where structural changes significantly enhance the interlayer coupling. This results in a bonding-antibonding splitting in the Hubbard bands, while the Mott gap remains dominant. Our discovery provides a simple and seminal model system for investigating Mott physics and other emerging correlated states.

Original language	English
Article number	041049
Journal	Physical Review X
Volume	13
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevX.13.041049
Publication status	Published - Oct 2023

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@article{2304c9f6036c4f57839d46950d5b166d,

title = "Discovery of a Single-Band Mott Insulator in a van der Waals Flat-Band Compound",

abstract = "The Mott insulator provides an excellent foundation for exploring a wide range of strongly correlated physical phenomena, such as high-temperature superconductivity, quantum spin liquid, and colossal magnetoresistance. A Mott insulator with the simplest degree of freedom is an ideal and highly desirable system for studying the fundamental physics of Mottness. In this study, we have unambiguously identified such an anticipated Mott insulator in a van der Waals layered compound Nb3Cl8. In the high-temperature phase, where interlayer coupling is negligible, density functional theory calculations for the monolayer of Nb3Cl8 suggest a half-filled flat band at the Fermi level, whereas angle-resolved photoemission spectroscopy experiments observe a large gap. This observation is perfectly reproduced by dynamical mean-field theory calculations considering strong electron correlations, indicating a correlation-driven Mott insulator state. Since this half-filled band derived from a single 2a1 orbital is isolated from all other bands, the monolayer of Nb3Cl8 is an ideal realization of the celebrated single-band Hubbard model. Upon decreasing the temperature, the bulk system undergoes a phase transition, where structural changes significantly enhance the interlayer coupling. This results in a bonding-antibonding splitting in the Hubbard bands, while the Mott gap remains dominant. Our discovery provides a simple and seminal model system for investigating Mott physics and other emerging correlated states.",

author = "Shunye Gao and Shuai Zhang and Cuixiang Wang and Shaohua Yan and Xin Han and Xuecong Ji and Wei Tao and Jingtong Liu and Tiantian Wang and Shuaikang Yuan and Gexing Qu and Ziyan Chen and Yongzhao Zhang and Jierui Huang and Mojun Pan and Shiyu Peng and Yong Hu and Hang Li and Yaobo Huang and Hui Zhou and Sheng Meng and Liu Yang and Zhiwei Wang and Yugui Yao and Zhiguo Chen and Ming Shi and Hong Ding and Huaixin Yang and Kun Jiang and Yunliang Li and Hechang Lei and Youguo Shi and Hongming Weng and Tian Qian",

note = "Publisher Copyright: {\textcopyright} 2023 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the {"}https://creativecommons.org/licenses/by/4.0/{"}Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.",

year = "2023",

month = oct,

doi = "10.1103/PhysRevX.13.041049",

language = "English",

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Gao, S, Zhang, S, Wang, C, Yan, S, Han, X, Ji, X, Tao, W, Liu, J, Wang, T, Yuan, S, Qu, G, Chen, Z, Zhang, Y, Huang, J, Pan, M, Peng, S, Hu, Y, Li, H, Huang, Y, Zhou, H, Meng, S, Yang, L, Wang, Z , Yao, Y, Chen, Z, Shi, M, Ding, H, Yang, H, Jiang, K, Li, Y, Lei, H, Shi, Y, Weng, H & Qian, T 2023, 'Discovery of a Single-Band Mott Insulator in a van der Waals Flat-Band Compound', Physical Review X, vol. 13, no. 4, 041049. https://doi.org/10.1103/PhysRevX.13.041049

TY - JOUR

T1 - Discovery of a Single-Band Mott Insulator in a van der Waals Flat-Band Compound

AU - Gao, Shunye

AU - Zhang, Shuai

AU - Wang, Cuixiang

AU - Yan, Shaohua

AU - Han, Xin

AU - Ji, Xuecong

AU - Tao, Wei

AU - Liu, Jingtong

AU - Wang, Tiantian

AU - Yuan, Shuaikang

AU - Qu, Gexing

AU - Chen, Ziyan

AU - Zhang, Yongzhao

AU - Huang, Jierui

AU - Pan, Mojun

AU - Peng, Shiyu

AU - Hu, Yong

AU - Li, Hang

AU - Huang, Yaobo

AU - Zhou, Hui

AU - Meng, Sheng

AU - Yang, Liu

AU - Wang, Zhiwei

AU - Yao, Yugui

AU - Chen, Zhiguo

AU - Shi, Ming

AU - Ding, Hong

AU - Yang, Huaixin

AU - Jiang, Kun

AU - Li, Yunliang

AU - Lei, Hechang

AU - Shi, Youguo

AU - Weng, Hongming

AU - Qian, Tian

N1 - Publisher Copyright: © 2023 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the "https://creativecommons.org/licenses/by/4.0/"Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

PY - 2023/10

Y1 - 2023/10

N2 - The Mott insulator provides an excellent foundation for exploring a wide range of strongly correlated physical phenomena, such as high-temperature superconductivity, quantum spin liquid, and colossal magnetoresistance. A Mott insulator with the simplest degree of freedom is an ideal and highly desirable system for studying the fundamental physics of Mottness. In this study, we have unambiguously identified such an anticipated Mott insulator in a van der Waals layered compound Nb3Cl8. In the high-temperature phase, where interlayer coupling is negligible, density functional theory calculations for the monolayer of Nb3Cl8 suggest a half-filled flat band at the Fermi level, whereas angle-resolved photoemission spectroscopy experiments observe a large gap. This observation is perfectly reproduced by dynamical mean-field theory calculations considering strong electron correlations, indicating a correlation-driven Mott insulator state. Since this half-filled band derived from a single 2a1 orbital is isolated from all other bands, the monolayer of Nb3Cl8 is an ideal realization of the celebrated single-band Hubbard model. Upon decreasing the temperature, the bulk system undergoes a phase transition, where structural changes significantly enhance the interlayer coupling. This results in a bonding-antibonding splitting in the Hubbard bands, while the Mott gap remains dominant. Our discovery provides a simple and seminal model system for investigating Mott physics and other emerging correlated states.

AB - The Mott insulator provides an excellent foundation for exploring a wide range of strongly correlated physical phenomena, such as high-temperature superconductivity, quantum spin liquid, and colossal magnetoresistance. A Mott insulator with the simplest degree of freedom is an ideal and highly desirable system for studying the fundamental physics of Mottness. In this study, we have unambiguously identified such an anticipated Mott insulator in a van der Waals layered compound Nb3Cl8. In the high-temperature phase, where interlayer coupling is negligible, density functional theory calculations for the monolayer of Nb3Cl8 suggest a half-filled flat band at the Fermi level, whereas angle-resolved photoemission spectroscopy experiments observe a large gap. This observation is perfectly reproduced by dynamical mean-field theory calculations considering strong electron correlations, indicating a correlation-driven Mott insulator state. Since this half-filled band derived from a single 2a1 orbital is isolated from all other bands, the monolayer of Nb3Cl8 is an ideal realization of the celebrated single-band Hubbard model. Upon decreasing the temperature, the bulk system undergoes a phase transition, where structural changes significantly enhance the interlayer coupling. This results in a bonding-antibonding splitting in the Hubbard bands, while the Mott gap remains dominant. Our discovery provides a simple and seminal model system for investigating Mott physics and other emerging correlated states.

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DO - 10.1103/PhysRevX.13.041049

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VL - 13

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Discovery of a Single-Band Mott Insulator in a van der Waals Flat-Band Compound

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