Fulleride Superconductivity Tuned by Elastic Strain Due to Cation Compositional Disorder

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2024 Sep 12

PMID 39263659

Authors

H Esma Okur

Ross H Colman

Yasuhiro Takabayashi

Peter Jeglic

Yasuo Ohishi

Kenichi Kato

Denis Arcon

Yoshiki Kubota

Kosmas Prassides

Affiliations

Soon will be listed here.

Abstract

Dynamical fluctuations of the elastic strain in strongly correlated systems are known to affect the onset of metal-to-insulator or superconducting transitions. Here we report their effect on the properties of a family of bandwidth-controlled alkali-intercalated fullerene superconductors. We introduce elastic strain through static local structural disorder in a systematic and controllable way in the fcc-structured K Cs C (with potassium content, 0.22 ≤ ≤ 2) series of compositions by utilizing the difference in size between the K and Cs co-dopants. The occurrence of the crossover from the Mott-Jahn-Teller insulating (MJTI) state into the strongly correlated Jahn-Teller metal (JTM) on cooling is evidenced for the compositions with < 1.28 by both synchrotron X-ray powder diffraction (SXRPD) - anomalous reduction of the unit cell volume - and Cs NMR spectroscopy - sudden suppression in the Cs spin-lattice relaxation rates. The emerging superconducting state with a maximum critical temperature, = 30.9 K shows a characteristic dome-like dependence on the unit-cell volume or equivalently, on the ratio between the on-site Coulomb repulsion, , and the bandwidth, . However, compared to the parent CsC composition in which cation disorder effects are completely absent, the maximum is lower by ∼12%. The reduction in displays a linear dependence on the variance of the tetrahedral-site cation size, , thus establishing a clear link between structural-disorder-induced attenuation of critical elastic strain fluctuations and the electronic ground state.

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