Dissipative conductivity of a dirty superconductor with Dynes subgap states under a dc bias current up to the depairing current density

Abstract

We study the dissipative conductivity σ1 of a dirty superconductor with a finite Dynes parameter under a dc-biased weak time-dependent field. The Usadel equation for the current-carrying state is solved to calculate the pair potential, penetration depth, supercurrent density, and quasiparticle spectrum. It is shown that, while the depairing current density jd for =0 is coincident with the Kupriyanov-Lukichev theory, a finite decreases the superfluid density, resulting in a reduction of jd. The broadening of the peaks of the quasiparticle density of states induced by a combination of a finite and a dc bias can reduce σ1 below that for the ideal dirty BCS superconductor with =0, while subgap states at Fermi level proportional to results in a residual conductivity at T 0. We find the optimum combination of and the dc bias to minimize σ1 by scanning all and all currents up to jd. By using the results, it is possible to improve jd and reduce electromagnetic dissipation in various superconducting quantum devices.