Theory of Two-level Tunneling Systems in Superconductors

Abstract: We develop a field theory formulation for the interaction of an ensemble of two-level tunneling systems (TLS) with the electronic states of a superconductor. Predictions for the impact of two-level tunneling systems on superconductivity are presented, including $T_c$ and spectrum of quasiparticle states for conventional BCS superconductors. We show that non-magnetic TLS impurities in conventional s-wave superconductors can act as pair-breaking or pair-enhancing defects depending on the level population of the distribution of TLS impurities. We present calculations of the enhancement of superconductivity, both $T_c$ and the order parameter, for TLS defects in thermal equilibrium with the electrons and lattice. The scattering of quasiparticles by TLS impurities leads to sub-gap states below the bulk excitation gap, $\Delta$, as well as resonances in the continuum above $\Delta$. The energies and spectral weights of these states depend on the distribution of tunnel splittings, while the spectral weights are particularly sensitive to the level occupation of the TLS impurities. Under microwave excitation, or decoupling from the thermal bath, a nonequilibrium level population of the TLS distribution generates subgap quasiparticle states near the Fermi level which contribute to dissipation and thus degrade the performance of superconducting devices at low temperatures.