Migdal-Eliashberg equations - the effective model for superconducting state in H3S

Abstract

The high-temperature superconducting state in sulfur trihydride (TC=203~K) has been investigated in the context of the non-adiabatic and anharmonic effects. The Migdal-Eliashberg equations and the extended Eliashberg equations, which include the lowest-order vertex corrections, have been solved numerically in the self-consistent way. For R3m crystal structure, the lowest-order vertex corrections decrease the value of the Coulomb pseudopotential from 0.123 to 0.108. The anharmonic effects work antagonistically in relation to the vertex corrections shifting the value of μ to 0.156. The studies conducted for the structure Im3m, where the Eliashberg function includes both the non-adiabatic and anharmonic effects, prove the even higher value of μ=0.185. Independently of the assumed method of the analysis, the nearly identical no mean-field dependence of the order parameter on the temperature was obtained: 2(0)/kBTC 4.7 - due to the significant strong-coupling and retardation effects: λ 2 and kBTC ω 0.15-0.19. It means that the classical equations of Migdal-Eliashberg can be treated as a correct effective model for the superconducting state in H3S. This paper has shown that the McMillan or Allen-Dynes formulas substantially lower the value of the critical temperature in relation to the result obtained with the Eliashberg equations.