First-principles study of the pressure and crystal-structure dependences of the superconducting transition temperature in compressed sulfur hydrides

Abstract

We calculate superconducting transition temperatures (T c) in sulfur hydrides H2S and H3S from first principles using the density functional theory for superconductors. At pressures of 150 GPa, the high values of T c (130 K) observed in the recent experiment [A. P. Drozdov, M. I. Eremets, and I. A. Troyan, arXiv:1412.0460] are accurately reproduced by assuming that H2S decomposes into R3m-H3S and S. For the higher pressures, the calculated T cs for Im3m-H3S are systematically higher than those for R3m-H3S and the experimentally observed maximum value (190 K), which suggests the possibility of another higher-T c phase. We also quantify the isotope effect from first principles and demonstrate that the isotope effect coefficient can be larger than the conventional value (0.5) when multiple structural phases energetically compete.