Pseudogap and zero-bias anomaly due to fluctuation suppression of quasiparticle tunneling

Abstract

We study the effect of superconducting fluctuations on the tunnel current-voltage characteristics of disordered superconducting films placed in a perpendicular magnetic field, H, in the whole H-T phase diagram outside the superconducting region. This tunnel-current is experimentally accessible by STM measurements. In the domain of temperatures T≥ Tc0 and relatively weak fields H Hc2(0) we reproduce existing results for the zero-voltage tunneling conductance, but also discover an important nonlinear contribution, which appears due to dynamic fluctuation modes and results in the formation of a strong zero-bias anomaly (ZBA) on the scale eV kB(T-Tc0). At large voltages (eV kBTc0) these modes, together with the contribution from static fluctuations, form a pseudogap maximum. At low temperatures, with magnetic field values near Hc2(0), fluctuations acquire quantum character and the general picture of the voltage dependent tunneling conductance resembles that one close to Tc0, where the role of temperature and magnetic field are exchanged. In particular, a gap-like structure appears with maximum at eV BCS and a sharp ZBA on the scale eV BCS(H/Hc2(0)-1). The complete expression for the tunneling current at arbitrary fields and temperatures can be evaluated only numerically, which is presented in detail.