Fluctuoscopy of Disordered Two-Dimensional Superconductors

TL;DR

This paper provides a comprehensive theoretical analysis of fluctuation conductivity in disordered two-dimensional superconductors under magnetic fields, deriving explicit expressions and comparing with experiments to understand quantum fluctuations near critical points.

Contribution

The authors derive the complete fluctuation conductivity surface in the temperature-magnetic field phase diagram, including asymptotic behaviors and experimental comparisons.

Findings

The fluctuation conductivity surface becomes trough-shaped and negative at low temperatures.

Close to the quantum phase transition, fluctuation conductivity is non-monotonic.

Superconducting fluctuations form a quantum liquid with long coherence length and slow relaxation.

Abstract

We revise the long studied problem of fluctuation conductivity (FC) in disordered two-dimensional superconductors placed in a perpendicular magnetic field by finally deriving the complete solution in the temperature-magnetic field phase diagram. The obtained expressions allow both to perform straightforward (numerical) calculation of the FC surface $\delta\sigma_{xx}^{(\mathrm{tot})}(T,H)$ and to get asymptotic expressions in all its qualitatively different domains. This surface becomes in particular non-trivial at low temperatures, where it is trough-shaped with $% \delta\sigma_{xx}^{(\mathrm{tot})}(T,H)<0$. In this region, close to the quantum phase transition, $\delta\sigma_{xx}^{(\mathrm{tot})}(T,H=\mathrm{const})$ is non-monotonic, in agreement with experimental findings. We reanalyzed and present comparisons to several experimental measurements. Based on our results we derive a qualitative picture of superconducting fluctuations close to $H_{\mathrm{c2}}(0) $ and T=0 where fluctuation Cooper pairs rotate with cyclotron frequency $\omega_{c}\sim\Delta_{\mathrm{BCS}}^{-1}$ and Larmor radius $\sim \xi_{\mathrm{BCS}}$, forming some kind of quantum liquid with long coherence length $\xi_{\mathrm{QF}}\gg\xi_{\mathrm{BCS}}$ and slow relaxation ($\tau_{\mathrm{QF}}\gg\hbar\Delta_{\mathrm{BCS}}^{-1}$).