Dynamic pair-breaking current, critical superfluid velocity and nonlinear electromagnetic response of nonequilibrium superconductors

Abstract

We report numerical calculations of a dynamic pairbreaking current density Jd and a critical superfluid velocity vd in a nonequilibrium superconductor carrying a uniform, large-amplitude ac current density J(t)=Ja t with well below the gap frequency 0/. The dependencies Jd(,T) and vd(,T) near the critical temperature Tc were calculated from either the full time-dependent nonequilibrium equations for a dirty s-wave superconductor and the time-dependent Ginzburg-Landau (TDGL) equations for a gapped superconductor, taking into account the GL relaxation time of the order parameter τGL and the inelastic electron-phonon relaxation time of quasiparticles τE. We show that both approaches give similar frequency dependencies of Jd() and vd() which gradually increase from their static pairbreaking GL values Jc and vc at τE 1 to 2Jc and 2vc at τE 1. Here Jd, vd and a dynamic superheating field at which the Meissner state becomes unstable were calculated in two different regimes of a fixed ac current and a fixed ac superfluid velocity induced by the applied ac magnetic field H=Ha t in a thin superconducting filament or a type-II superconductor with a large GL parameter. We also calculated a nonlinear electromagnetic response of a nonequilibrium superconducting state, particularly a dynamic kinetic inductance and a dissipative quasiparticle conductivity, taking into account the oscillatory dynamics of superconducting condensate and the kinetics of quasiparticles driven by a strong ac current. It is shown that an ac current density produces multiple harmonics of the electric field, the amplitudes of the higher-order harmonics diminishing as τE increases.