What superconducts in sulfur hydrides under pressure, and why

Abstract

The recent discovery of superconductivity at 190~K in highly compressed H2S is spectacular not only because it sets a record high critical temperature, but because it does so in a material that appears to be, and we argue here that it is, a conventional strong-coupling BCS superconductor. Intriguingly, superconductivity in the observed pressure and temperature range was predicted theoretically in a similar compound H3S. Several important questions about this remarkable result, however, are left unanswered: (1) Does the stoichiometry of the superconducting compound differ from the nominal composition, and could it be the predicted H3S compound? (2) Is the physical origin of the anomalously high critical temperature related only to the high H phonon frequencies, or does strong electron-ion coupling play a role? We show that at experimentally relevant pressures H2S is unstable, decomposing into H3S and S, and that H3S has a record high Tc due to its covalent bonds driven metallic. The main reason for this extraordinarily high Tc in H3S as compared with MgB2, another compound with a similar superconductivity mechanism, is the high vibrational frequency of the much lighter H atoms.