Ferroelectric quantum critical point in superconducting hydrides: The case of H3S

Abstract

H3S sulfur hydride has been widely investigated for its high superconducting critical temperature Tc of 203 K at about pc = 155 GPa. Despite being the precursor of superconducting hydrides, a detailed picture of its phase diagram in an extended temperature and pressure range is still missing. To determine it with inclusion of both thermal and quantum effects, we carry out path integral molecular dynamics combined to a MACE neural network potential trained on BLYP density functional theory configurations. The resulting H3S phase diagram is characterized by the ferroelectric transition between the Im3m and R3m phases, which originates from a quantum critical point (QCP) located at pQCP ≈ 134 GPa. We show that the experimental Tc peak falls into a paraelectric region of large nuclear quantum fluctuations above the ferroelectric QCP, as measured by local phonon Green's functions resolved in imaginary time, where fluctuating dipole moments are at play. We study the critical behavior of the system in the proximity of the QCP by a finite-size scaling analysis, showing that it belongs to the 4D Ising universality class. We finally discuss its implications for the superconducting state.