Reduction of Dissipative Nonlinear Conductivity of Superconductors by Static and Microwave Magnetic Fields

Abstract

A theory of dissipative nonlinear conductivity, σ1(ω,H), of s-wave superconductors under strong electromagnetic fields at low temperatures is proposed. Closed-form expressions for σ1(H) and the surface resistance Rs(ω,H) are obtained in the nonequilibrium dirty limit for which σ1(H) has a significant minimum as a function of a low-frequency (ω kBT) magnetic field H. The calculated microwave suppression of Rs(H) is in good agreement with recent experiments on alloyed Nb resonator cavities. It is shown that superimposed dc and ac fields, H=H0+Haω t, can be used to reduce ac dissipation in thin film nanostructures by tuning σ1(H0) with the dc field.