Orbital-selective charge-density wave in TaTe4

R. Z. Xu; X. Du; J. S. Zhou; X. Gu; Q. Q. Zhang; Y. D. Li; W. X. Zhao; F. W. Zheng; M. Arita; K. Shimada; T. K. Kim; C. Cacho; Y. F. Guo; Z. K. Liu; Y. L. Chen; L. X. Yang

doi:10.1038/s41535-023-00573-8

Orbital-selective charge-density wave in TaTe₄

R. Z. Xu, X. Du, J. S. Zhou, X. Gu, Q. Q. Zhang, Y. D. Li, W. X. Zhao, F. W. Zheng, M. Arita, K. Shimada, T. K. Kim, C. Cacho, Y. F. Guo, Z. K. Liu, Y. L. Chen^*, L. X. Yang^*

^*Corresponding author for this work

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

2 Citations (Scopus)

Abstract

TaTe₄, a metallic charge-density wave (CDW) material discovered decades ago, has attracted renewed attention due to its rich interesting properties, such as pressure-induced superconductivity and candidate nontrivial topological phase. Here, using high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we systematically investigate the electronic structure of TaTe₄. At 26 K, we observe a CDW gap as large as 290 meV, which persists up to 500 K. The CDW-modulated band structure shows a complex reconstruction that closely correlates with the lattice distortion. Inside the CDW gap, there exist highly dispersive energy bands contributing to the remnant Fermi surface and metallic behavior in the CDW state. Interestingly, our ab initio calculation reveals that the large CDW gap mainly opens in the electronic states with out-of-plane orbital components, while the in-gap metallic states originate from in-plane orbitals, suggesting an orbital texture that couples with the CDW order. Our results shed light on the interplay between electron, lattice, and orbital in quasi-one-dimensional CDW materials.

Original language	English
Article number	44
Journal	npj Quantum Materials
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41535-023-00573-8
Publication status	Published - Dec 2023
Externally published	Yes

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Xu, R. Z., Du, X., Zhou, J. S., Gu, X., Zhang, Q. Q., Li, Y. D., Zhao, W. X., Zheng, F. W., Arita, M., Shimada, K., Kim, T. K., Cacho, C., Guo, Y. F., Liu, Z. K., Chen, Y. L., & Yang, L. X. (2023). Orbital-selective charge-density wave in TaTe₄. npj Quantum Materials, 8(1), Article 44. https://doi.org/10.1038/s41535-023-00573-8

@article{3d0d191ebd5d470ebc037d9fc81e2f50,

title = "Orbital-selective charge-density wave in TaTe4",

abstract = "TaTe4, a metallic charge-density wave (CDW) material discovered decades ago, has attracted renewed attention due to its rich interesting properties, such as pressure-induced superconductivity and candidate nontrivial topological phase. Here, using high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we systematically investigate the electronic structure of TaTe4. At 26 K, we observe a CDW gap as large as 290 meV, which persists up to 500 K. The CDW-modulated band structure shows a complex reconstruction that closely correlates with the lattice distortion. Inside the CDW gap, there exist highly dispersive energy bands contributing to the remnant Fermi surface and metallic behavior in the CDW state. Interestingly, our ab initio calculation reveals that the large CDW gap mainly opens in the electronic states with out-of-plane orbital components, while the in-gap metallic states originate from in-plane orbitals, suggesting an orbital texture that couples with the CDW order. Our results shed light on the interplay between electron, lattice, and orbital in quasi-one-dimensional CDW materials.",

author = "Xu, {R. Z.} and X. Du and Zhou, {J. S.} and X. Gu and Zhang, {Q. Q.} and Li, {Y. D.} and Zhao, {W. X.} and Zheng, {F. W.} and M. Arita and K. Shimada and Kim, {T. K.} and C. Cacho and Guo, {Y. F.} and Liu, {Z. K.} and Chen, {Y. L.} and Yang, {L. X.}",

note = "Publisher Copyright: {\textcopyright} 2023, Springer Nature Limited.",

year = "2023",

month = dec,

doi = "10.1038/s41535-023-00573-8",

language = "English",

volume = "8",

journal = "npj Quantum Materials",

issn = "2397-4648",

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T1 - Orbital-selective charge-density wave in TaTe4

AU - Xu, R. Z.

AU - Du, X.

AU - Zhou, J. S.

AU - Gu, X.

AU - Zhang, Q. Q.

AU - Li, Y. D.

AU - Zhao, W. X.

AU - Zheng, F. W.

AU - Arita, M.

AU - Shimada, K.

AU - Kim, T. K.

AU - Cacho, C.

AU - Guo, Y. F.

AU - Liu, Z. K.

AU - Chen, Y. L.

AU - Yang, L. X.

PY - 2023/12

Y1 - 2023/12

N2 - TaTe4, a metallic charge-density wave (CDW) material discovered decades ago, has attracted renewed attention due to its rich interesting properties, such as pressure-induced superconductivity and candidate nontrivial topological phase. Here, using high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we systematically investigate the electronic structure of TaTe4. At 26 K, we observe a CDW gap as large as 290 meV, which persists up to 500 K. The CDW-modulated band structure shows a complex reconstruction that closely correlates with the lattice distortion. Inside the CDW gap, there exist highly dispersive energy bands contributing to the remnant Fermi surface and metallic behavior in the CDW state. Interestingly, our ab initio calculation reveals that the large CDW gap mainly opens in the electronic states with out-of-plane orbital components, while the in-gap metallic states originate from in-plane orbitals, suggesting an orbital texture that couples with the CDW order. Our results shed light on the interplay between electron, lattice, and orbital in quasi-one-dimensional CDW materials.

AB - TaTe4, a metallic charge-density wave (CDW) material discovered decades ago, has attracted renewed attention due to its rich interesting properties, such as pressure-induced superconductivity and candidate nontrivial topological phase. Here, using high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we systematically investigate the electronic structure of TaTe4. At 26 K, we observe a CDW gap as large as 290 meV, which persists up to 500 K. The CDW-modulated band structure shows a complex reconstruction that closely correlates with the lattice distortion. Inside the CDW gap, there exist highly dispersive energy bands contributing to the remnant Fermi surface and metallic behavior in the CDW state. Interestingly, our ab initio calculation reveals that the large CDW gap mainly opens in the electronic states with out-of-plane orbital components, while the in-gap metallic states originate from in-plane orbitals, suggesting an orbital texture that couples with the CDW order. Our results shed light on the interplay between electron, lattice, and orbital in quasi-one-dimensional CDW materials.

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JO - npj Quantum Materials

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ER -

Orbital-selective charge-density wave in TaTe₄

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