Strongly correlated superconductivity in a copper-based metal-organic framework with a perfect kagome lattice

T. Takenaka; K. Ishihara; M. Roppongi; Y. Miao; Y. Mizukami; T. Makita; J. Tsurumi; S. Watanabe; J. Takeya; M. Yamashita; K. Torizuka; Y. Uwatoko; T. Sasaki; X. Huang; W. Xu; D. Zhu; N. Su; J. G. Cheng; T. Shibauchi; K. Hashimoto

doi:10.1126/sciadv.abf3996

Strongly correlated superconductivity in a copper-based metal-organic framework with a perfect kagome lattice

T. Takenaka, K. Ishihara, M. Roppongi, Y. Miao, Y. Mizukami, T. Makita, J. Tsurumi, S. Watanabe, J. Takeya, M. Yamashita, K. Torizuka, Y. Uwatoko, T. Sasaki, X. Huang, W. Xu, D. Zhu, N. Su, J. G. Cheng, T. Shibauchi, K. Hashimoto

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

26 Citations (Scopus)

Abstract

Metal-organic frameworks (MOFs), which are self-assemblies of metal ions and organic ligands, provide a tunable platform to search a new state of matter. A two-dimensional (2D) perfect kagome lattice, whose geometrical frustration is a key to realizing quantum spin liquids, has been formed in the − d conjugated 2D MOF [Cu₃(C₆S₆)]_n (Cu-BHT). The recent discovery of its superconductivity with a critical temperature T_c of 0.25 kelvin raises fundamental questions about the nature of electron pairing. Here, we show that Cu-BHT is a strongly correlated unconventional superconductor with extremely low superfluid density. A nonexponential temperature dependence of superfluid density is observed, indicating the possible presence of superconducting gap nodes. The magnitude of superfluid density is much smaller than those in conventional superconductors and follows the Uemura’s relation of strongly correlated superconductors. These results imply that the unconventional superconductivity in Cu-BHT originates from electron correlations related to spin fluctuations of kagome lattice.

Original language	English
Article number	eabf3996
Journal	Science Advances
Volume	7
Issue number	12
DOIs	https://doi.org/10.1126/sciadv.abf3996
Publication status	Published - 2021 Mar 17
Externally published	Yes

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Takenaka, T., Ishihara, K., Roppongi, M., Miao, Y., Mizukami, Y., Makita, T., Tsurumi, J., Watanabe, S., Takeya, J., Yamashita, M., Torizuka, K., Uwatoko, Y., Sasaki, T., Huang, X., Xu, W., Zhu, D., Su, N., Cheng, J. G., Shibauchi, T., & Hashimoto, K. (2021). Strongly correlated superconductivity in a copper-based metal-organic framework with a perfect kagome lattice. Science Advances, 7(12), [eabf3996]. https://doi.org/10.1126/sciadv.abf3996

Takenaka, T, Ishihara, K, Roppongi, M, Miao, Y, Mizukami, Y, Makita, T, Tsurumi, J, Watanabe, S, Takeya, J, Yamashita, M, Torizuka, K, Uwatoko, Y, Sasaki, T, Huang, X, Xu, W, Zhu, D, Su, N, Cheng, JG, Shibauchi, T & Hashimoto, K 2021, 'Strongly correlated superconductivity in a copper-based metal-organic framework with a perfect kagome lattice', Science Advances, vol. 7, no. 12, eabf3996. https://doi.org/10.1126/sciadv.abf3996

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abstract = "Metal-organic frameworks (MOFs), which are self-assemblies of metal ions and organic ligands, provide a tunable platform to search a new state of matter. A two-dimensional (2D) perfect kagome lattice, whose geometrical frustration is a key to realizing quantum spin liquids, has been formed in the − d conjugated 2D MOF [Cu3(C6S6)]n (Cu-BHT). The recent discovery of its superconductivity with a critical temperature Tc of 0.25 kelvin raises fundamental questions about the nature of electron pairing. Here, we show that Cu-BHT is a strongly correlated unconventional superconductor with extremely low superfluid density. A nonexponential temperature dependence of superfluid density is observed, indicating the possible presence of superconducting gap nodes. The magnitude of superfluid density is much smaller than those in conventional superconductors and follows the Uemura{\textquoteright}s relation of strongly correlated superconductors. These results imply that the unconventional superconductivity in Cu-BHT originates from electron correlations related to spin fluctuations of kagome lattice.",

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AU - Takenaka, T.

AU - Ishihara, K.

AU - Roppongi, M.

AU - Miao, Y.

AU - Mizukami, Y.

AU - Makita, T.

AU - Tsurumi, J.

AU - Watanabe, S.

AU - Takeya, J.

AU - Yamashita, M.

AU - Torizuka, K.

AU - Uwatoko, Y.

AU - Sasaki, T.

AU - Huang, X.

AU - Xu, W.

AU - Zhu, D.

AU - Su, N.

AU - Cheng, J. G.

AU - Shibauchi, T.

AU - Hashimoto, K.

PY - 2021/3/17

Y1 - 2021/3/17

N2 - Metal-organic frameworks (MOFs), which are self-assemblies of metal ions and organic ligands, provide a tunable platform to search a new state of matter. A two-dimensional (2D) perfect kagome lattice, whose geometrical frustration is a key to realizing quantum spin liquids, has been formed in the − d conjugated 2D MOF [Cu3(C6S6)]n (Cu-BHT). The recent discovery of its superconductivity with a critical temperature Tc of 0.25 kelvin raises fundamental questions about the nature of electron pairing. Here, we show that Cu-BHT is a strongly correlated unconventional superconductor with extremely low superfluid density. A nonexponential temperature dependence of superfluid density is observed, indicating the possible presence of superconducting gap nodes. The magnitude of superfluid density is much smaller than those in conventional superconductors and follows the Uemura’s relation of strongly correlated superconductors. These results imply that the unconventional superconductivity in Cu-BHT originates from electron correlations related to spin fluctuations of kagome lattice.

AB - Metal-organic frameworks (MOFs), which are self-assemblies of metal ions and organic ligands, provide a tunable platform to search a new state of matter. A two-dimensional (2D) perfect kagome lattice, whose geometrical frustration is a key to realizing quantum spin liquids, has been formed in the − d conjugated 2D MOF [Cu3(C6S6)]n (Cu-BHT). The recent discovery of its superconductivity with a critical temperature Tc of 0.25 kelvin raises fundamental questions about the nature of electron pairing. Here, we show that Cu-BHT is a strongly correlated unconventional superconductor with extremely low superfluid density. A nonexponential temperature dependence of superfluid density is observed, indicating the possible presence of superconducting gap nodes. The magnitude of superfluid density is much smaller than those in conventional superconductors and follows the Uemura’s relation of strongly correlated superconductors. These results imply that the unconventional superconductivity in Cu-BHT originates from electron correlations related to spin fluctuations of kagome lattice.

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Strongly correlated superconductivity in a copper-based metal-organic framework with a perfect kagome lattice

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