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Main Authors: Yang, Yi-Chen, Cho, Soohyun, Li, Tong-Rui, Liu, Xiang-Qi, Liu, Zheng-Tai, Jiang, Zhi-Cheng, Ding, Jian-Yang, Xia, Wei, Tao, Zi-Cheng, Liu, Jia-Yu, Jing, Wen-Chuan, Huang, Yu, Shi, Yu-Ming, Huh, Soonsang, Kondo, Takeshi, Sun, Zhe, Liu, Ji-Shan, Ye, Mao, Wang, Yi-Lin, Guo, Yan-Feng, Shen, Da-Wei
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.03765
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author Yang, Yi-Chen
Cho, Soohyun
Li, Tong-Rui
Liu, Xiang-Qi
Liu, Zheng-Tai
Jiang, Zhi-Cheng
Ding, Jian-Yang
Xia, Wei
Tao, Zi-Cheng
Liu, Jia-Yu
Jing, Wen-Chuan
Huang, Yu
Shi, Yu-Ming
Huh, Soonsang
Kondo, Takeshi
Sun, Zhe
Liu, Ji-Shan
Ye, Mao
Wang, Yi-Lin
Guo, Yan-Feng
Shen, Da-Wei
author_facet Yang, Yi-Chen
Cho, Soohyun
Li, Tong-Rui
Liu, Xiang-Qi
Liu, Zheng-Tai
Jiang, Zhi-Cheng
Ding, Jian-Yang
Xia, Wei
Tao, Zi-Cheng
Liu, Jia-Yu
Jing, Wen-Chuan
Huang, Yu
Shi, Yu-Ming
Huh, Soonsang
Kondo, Takeshi
Sun, Zhe
Liu, Ji-Shan
Ye, Mao
Wang, Yi-Lin
Guo, Yan-Feng
Shen, Da-Wei
contents The charge density wave (CDW), as a hallmark of vanadium-based kagome superconductor AV3Sb5 (A = K, Rb, Cs), has attracted intensive attention. However, the fundamental controversy regarding the underlying mechanism of CDW therein persists. Recently, the vanadium-based bi-layered kagome metal ScV6Sn6, reported to exhibit a long-range charge order below 94 K, has emerged as a promising candidate to further clarify this core issue. Here, employing micro-focusing angle-resolved photoemission spectroscopy (μ-ARPES) and first-principles calculations, we systematically studied the unique CDW order in vanadium-based bi-layered kagome metals by comparing ScV6Sn6 with its isostructural counterpart YV6Sn6, which lacks a CDW ground state. Combining ARPES data and the corresponding joint density of states (DOS), we suggest that the VHS nesting mechanism might be invalid in these materials. Besides, in ScV6Sn6, we identified multiple hybridization energy gaps resulting from CDW-induced band folding, along with an anomalous band dispersion, implying a potential electron-phonon coupling driven mechanism underlying the formation of the CDW order. Our finding not only comprehensively maps the electronic structure of V-based bi-layer kagome metals but also provide constructive experimental evidence for the unique origin of CDW in this system.
format Preprint
id arxiv_https___arxiv_org_abs_2402_03765
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Unveiling the charge density wave mechanism in vanadium-based Bi-layered kagome metals
Yang, Yi-Chen
Cho, Soohyun
Li, Tong-Rui
Liu, Xiang-Qi
Liu, Zheng-Tai
Jiang, Zhi-Cheng
Ding, Jian-Yang
Xia, Wei
Tao, Zi-Cheng
Liu, Jia-Yu
Jing, Wen-Chuan
Huang, Yu
Shi, Yu-Ming
Huh, Soonsang
Kondo, Takeshi
Sun, Zhe
Liu, Ji-Shan
Ye, Mao
Wang, Yi-Lin
Guo, Yan-Feng
Shen, Da-Wei
Materials Science
The charge density wave (CDW), as a hallmark of vanadium-based kagome superconductor AV3Sb5 (A = K, Rb, Cs), has attracted intensive attention. However, the fundamental controversy regarding the underlying mechanism of CDW therein persists. Recently, the vanadium-based bi-layered kagome metal ScV6Sn6, reported to exhibit a long-range charge order below 94 K, has emerged as a promising candidate to further clarify this core issue. Here, employing micro-focusing angle-resolved photoemission spectroscopy (μ-ARPES) and first-principles calculations, we systematically studied the unique CDW order in vanadium-based bi-layered kagome metals by comparing ScV6Sn6 with its isostructural counterpart YV6Sn6, which lacks a CDW ground state. Combining ARPES data and the corresponding joint density of states (DOS), we suggest that the VHS nesting mechanism might be invalid in these materials. Besides, in ScV6Sn6, we identified multiple hybridization energy gaps resulting from CDW-induced band folding, along with an anomalous band dispersion, implying a potential electron-phonon coupling driven mechanism underlying the formation of the CDW order. Our finding not only comprehensively maps the electronic structure of V-based bi-layer kagome metals but also provide constructive experimental evidence for the unique origin of CDW in this system.
title Unveiling the charge density wave mechanism in vanadium-based Bi-layered kagome metals
topic Materials Science
url https://arxiv.org/abs/2402.03765