High-Tc superconductivity in H3S: Pressure effects on superconducting critical temperature and Cooper-Pairs Distribution Function

Abstract

We use first-principles calculations to study pressure effects on the vibrational and superconducting properties of H3S in the cubic Im3m phase for the pressure range where the superconducting critical temperature (Tc) was measured (155-225 GPa). The pressure effects were incorporated using the Functional Derivative Method (FDM). In this paper, we present for the first time, the Cooper-Pairs Distribution Functions Dcp(ω,Tc) for H3S, which will allow to identify the spectral regions where Cooper-Pairs formation at temperature Tc is more favorable. We analyzed in detail the pressure effects on the electron-phonon spectral density function α2F(ω) and phonon density of states (PhDOS) and their relationship with Tc. The FDM manages to reproduce the trend of the pressure dependence of critical temperature, in good agreement with experimental data in the range of 155 to 190 GPa. The Dcp(ω,Tc) suggests that the low-frequency vibration region is where Cooper-Pairs are possible, which means that S-vibrations have an important role in the H3S superconductivity properties.