The quantum nature of the superconducting hydrogen sulfide at finite temperatures

Abstract

H3S is believed to the most possible high-temperature superconducting (Tc) phase of hydrogen sulfide at 200 GPa. It's isotope substitution of hydrogen (H) by deuterium (D), however, shows an anomalous Tc decrease of 100 K at 140 to 160 GPa, much larger than the Bardeen-Cooper-Schrieffer theory prediction. Using ab initio path-integral molecular dynamics (PIMD), we show that the nuclear quantum effects (NQEs) influence the structures of H3S and D3S differently at finite temperatures and the interval when H3S possesses the symmetric high Tc structure while D3S does not is in agreement with, though their absolute values are lower than experiments. This is consistent with an earlier theoretical study using the stochastic self-consistent harmonic approximation method in descriptions of the nuclei at 0 K.The remaining discrepancy can be substantially improved when the electronic structures are calculated using a hybrid function. Our study presents a simple picture to interpret the isotope dependent of Tc and emphasizes the quantum nature in the high-pressure hydrogen sulfide system.