Pressure-Induced Double-Dome Superconductivity in Kagome Metals ATi3Bi5 (A = Cs, Rb)

J. Y. Nie; X. F. Yang; K. Y. Chen; X. Q. Liu; W. Xia; J. Wang; R. Zhang; D. Z. Dai; C. C. Zhao; C. P. Tu; H. L. Dong; X. B. Jin; J. K. Deng; X. Zhang; Y. F. Guo; S. Y. Li

doi:10.1088/0256-307X/42/7/070713

Pressure-Induced Double-Dome Superconductivity in Kagome Metals ATi₃Bi₅ (A = Cs, Rb)

J. Y. Nie
, X. F. Yang
, K. Y. Chen
, X. Q. Liu
, W. Xia
, J. Wang
, R. Zhang
, D. Z. Dai
, C. C. Zhao
, C. P. Tu
, H. L. Dong
, X. B. Jin
, J. K. Deng
, X. Zhang
, Y. F. Guo
, S. Y. Li

材料科学与工程学院

Fudan University
Shanghai Research Center for Quantum Sciences
Northwest Institute for Nonferrous Metal Research
ShanghaiTech University
ShanghaiTech Laboratory for Topological Physics
Center for High Pressure Science & Technology Advanced Research
Institute for Shanghai Advanced Research in Physical Sciences
Hefei National Laboratory
Collaborative Innovation Center of Advanced Microstructures

科研成果: 期刊稿件 › 文章 › 同行评审

3 引用（Scopus）

摘要

The recently discovered titanium-based kagome metal ATi₃Bi₅ (A = Cs, Rb) provides a new platform to explore novel quantum phenomena. In this work, the transport properties of ATi₃Bi₅ (A = Cs, Rb) are systematically investigated under high pressure. Although ATi₃Bi₅ (A = Cs, Rb) shows no evidence of superconductivity at ambient pressure, the pressure-induced double-dome superconductivity is observed in both compounds, resembling the superconducting phase diagram of AV₃Sb₅ (A = Cs, Rb, and K) under pressure. High-pressure X-ray diffraction measurements exclude the pressure-induced structural phase transition. A slope change in the c/a ratio was found between 12.4 and 14.9 GPa, indicating the occurrence of lattice distortion. The distinct changes in the electronic band structure revealed by first-principles calculations further explain the emergence of superconductivity in the two domes. These findings suggest that pressure can effectively tune the electronic properties of ATi₃Bi₅, providing new insights into the rich physics of kagome metals.

源语言	英语
文章编号	070713
期刊	Chinese Physics Letters
卷	42
期	7
DOI	https://doi.org/10.1088/0256-307X/42/7/070713
出版状态	已出版 - 1 7月 2025

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10.1088/0256-307X/42/7/070713

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引用此

Nie, J. Y., Yang, X. F., Chen, K. Y., Liu, X. Q., Xia, W., Wang, J., Zhang, R., Dai, D. Z., Zhao, C. C., Tu, C. P., Dong, H. L., Jin, X. B., Deng, J. K., Zhang, X., Guo, Y. F., & Li, S. Y. (2025). Pressure-Induced Double-Dome Superconductivity in Kagome Metals ATi₃Bi₅ (A = Cs, Rb). Chinese Physics Letters, 42(7), 文章 070713. https://doi.org/10.1088/0256-307X/42/7/070713

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title = "Pressure-Induced Double-Dome Superconductivity in Kagome Metals ATi3Bi5 (A = Cs, Rb)",

abstract = "The recently discovered titanium-based kagome metal ATi3Bi5 (A = Cs, Rb) provides a new platform to explore novel quantum phenomena. In this work, the transport properties of ATi3Bi5 (A = Cs, Rb) are systematically investigated under high pressure. Although ATi3Bi5 (A = Cs, Rb) shows no evidence of superconductivity at ambient pressure, the pressure-induced double-dome superconductivity is observed in both compounds, resembling the superconducting phase diagram of AV3Sb5 (A = Cs, Rb, and K) under pressure. High-pressure X-ray diffraction measurements exclude the pressure-induced structural phase transition. A slope change in the c/a ratio was found between 12.4 and 14.9 GPa, indicating the occurrence of lattice distortion. The distinct changes in the electronic band structure revealed by first-principles calculations further explain the emergence of superconductivity in the two domes. These findings suggest that pressure can effectively tune the electronic properties of ATi3Bi5, providing new insights into the rich physics of kagome metals.",

author = "Nie, \{J. Y.\} and Yang, \{X. F.\} and Chen, \{K. Y.\} and Liu, \{X. Q.\} and W. Xia and J. Wang and R. Zhang and Dai, \{D. Z.\} and Zhao, \{C. C.\} and Tu, \{C. P.\} and Dong, \{H. L.\} and Jin, \{X. B.\} and Deng, \{J. K.\} and X. Zhang and Guo, \{Y. F.\} and Li, \{S. Y.\}",

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AU - Nie, J. Y.

AU - Yang, X. F.

AU - Chen, K. Y.

AU - Liu, X. Q.

AU - Xia, W.

AU - Wang, J.

AU - Zhang, R.

AU - Dai, D. Z.

AU - Zhao, C. C.

AU - Tu, C. P.

AU - Dong, H. L.

AU - Jin, X. B.

AU - Deng, J. K.

AU - Zhang, X.

AU - Guo, Y. F.

AU - Li, S. Y.

PY - 2025/7/1

Y1 - 2025/7/1

N2 - The recently discovered titanium-based kagome metal ATi3Bi5 (A = Cs, Rb) provides a new platform to explore novel quantum phenomena. In this work, the transport properties of ATi3Bi5 (A = Cs, Rb) are systematically investigated under high pressure. Although ATi3Bi5 (A = Cs, Rb) shows no evidence of superconductivity at ambient pressure, the pressure-induced double-dome superconductivity is observed in both compounds, resembling the superconducting phase diagram of AV3Sb5 (A = Cs, Rb, and K) under pressure. High-pressure X-ray diffraction measurements exclude the pressure-induced structural phase transition. A slope change in the c/a ratio was found between 12.4 and 14.9 GPa, indicating the occurrence of lattice distortion. The distinct changes in the electronic band structure revealed by first-principles calculations further explain the emergence of superconductivity in the two domes. These findings suggest that pressure can effectively tune the electronic properties of ATi3Bi5, providing new insights into the rich physics of kagome metals.

AB - The recently discovered titanium-based kagome metal ATi3Bi5 (A = Cs, Rb) provides a new platform to explore novel quantum phenomena. In this work, the transport properties of ATi3Bi5 (A = Cs, Rb) are systematically investigated under high pressure. Although ATi3Bi5 (A = Cs, Rb) shows no evidence of superconductivity at ambient pressure, the pressure-induced double-dome superconductivity is observed in both compounds, resembling the superconducting phase diagram of AV3Sb5 (A = Cs, Rb, and K) under pressure. High-pressure X-ray diffraction measurements exclude the pressure-induced structural phase transition. A slope change in the c/a ratio was found between 12.4 and 14.9 GPa, indicating the occurrence of lattice distortion. The distinct changes in the electronic band structure revealed by first-principles calculations further explain the emergence of superconductivity in the two domes. These findings suggest that pressure can effectively tune the electronic properties of ATi3Bi5, providing new insights into the rich physics of kagome metals.

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JO - Chinese Physics Letters

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Pressure-Induced Double-Dome Superconductivity in Kagome Metals ATi3Bi5 (A = Cs, Rb)

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Pressure-Induced Double-Dome Superconductivity in Kagome Metals ATi₃Bi₅ (A = Cs, Rb)