Instability of Pa 3 Cs3C60 at ambient pressure and superconducting state of the FCC phase

Abstract

The alkali-doped fulleride Cs3C60, crystallized in the space group Fm 3m or Pm 3n, exhibits unconventional s-wave superconductivity under pressure with a maximum Tc 38 K. Recently, a new primitive-cubic-structured Cs3C60 phase corresponding to the space group Pa 3 has been reported (arXiv:2208.09429) and the authors observed superconductivity at ambient pressure. Using density-functional theory (DFT) calculations, we show that the proposed Pa 3 structure is not stable under ionic relaxation, but transforms into the FCC structure. We study the normal and superconducting state of the stable FCC phase at different temperatures and volumes using DFT plus dynamical mean-field theory (DFT+DMFT) in the Nambu formalism. As temperature increases, the transition between superconductor and normal metal (Mott insulator) at small (big) volume is found to be second (first) order. The recently developed maximum entropy analytic continuation method for the anomalous-self-energy is used to study the momentum-resolved spectra and optical conductivity.