Non-equilibrium superconductivity in superconducting resonators

Abstract

We have calculated the non-equilibrium quasiparticle and phonon distributions f(E), n(), where E and are the quasiparticle and phonon energies respectively, generated by the photons of the probe signal of a low temperature superconducting resonator SR operating well-below its transition temperature Tc as the absorbed probe power per unit volume Pabs was changed. The calculations give insight into a rate equation estimate which suggests that the quasiparticle distributions can be driven far from the thermal equilibrium value for typical readout powers. From f(E) the driven quasiparticle number density Nqp and lifetime τr were calculated. Using Nqp we defined an effective temperature TN* to describe the driven f(E). The lifetime was compared to the distribution averaged thermal lifetime at TN* and good agreement was found typically within a few percent. We used f(E) to model a representative SR. The complex conductivity and hence the frequency dependence of the experimentally measured forward scattering parameter S21 of the SR as a function of Pabs were found. The non-equilibrium S21 cannot be accurately modeled by a thermal distribution at an elevated temperature T21* having a higher quality-factor in all cases studied and for low Pabs T21* TN*. Using τr and Nqp we determined the achievable Noise Equivalent Power of the resonator used as a detector as a function of Pabs. Simpler expressions for TN* as a function of Pabs were derived which give a very good account of TN* and also Nqp and τr. We conclude that multiple photon absorption from the probe increases the quasiparticle number above the thermal background and ultimately limits the achievable NEP of the resonator.