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Temperature and quantum anharmonic lattice effects on stability and superconductivity in lutetium trihydride

Roman Lucrezi, Pedro P. Ferreira, Markus Aichhorn and Christoph Heil ()
Additional contact information
Roman Lucrezi: Graz University of Technology
Pedro P. Ferreira: Graz University of Technology
Markus Aichhorn: Graz University of Technology
Christoph Heil: Graz University of Technology

Nature Communications, 2024, vol. 15, issue 1, 1-7

Abstract: Abstract In this work, we resolve conflicting experimental and theoretical findings related to the dynamical stability and superconducting properties of $$Fm\bar{3}m$$ F m 3 ¯ m -LuH3, which was recently suggested as the parent phase harboring room-temperature superconductivity at near-ambient pressures. Including temperature and quantum anharmonic lattice effects in our calculations, we demonstrate that the theoretically predicted structural instability of the $$Fm\bar{3}m$$ F m 3 ¯ m phase near ambient pressures is suppressed for temperatures above 200 K. We provide a p–T phase diagram for stability up to pressures of 6 GPa, where the required temperature for stability is reduced to T > 80 K. We also determine the superconducting critical temperature Tc of $$Fm\bar{3}m$$ F m 3 ¯ m -LuH3 within the Migdal-Eliashberg formalism, using temperature- and quantum-anharmonically-corrected phonon dispersions, finding that the expected Tc for electron-phonon mediated superconductivity is in the range of 50–60 K, i.e., well below the temperatures required to stabilize the lattice. When considering moderate doping based on rigidly shifting the Fermi level, Tc decreases for both hole and electron doping. Our results thus provide evidence that any observed room-temperature superconductivity in pure or doped $$Fm\bar{3}m$$ F m 3 ¯ m -LuH3, if confirmed, cannot be explained by a conventional electron-phonon mediated pairing mechanism.

Date: 2024
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DOI: 10.1038/s41467-023-44326-4

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