Universal conductivity at a 2d superconductor-insulator transition: the effects of quenched disorder and Coulomb interaction

Abstract

We calculate the zero-temperature universal electrical conductivity at a superconductor-insulator transition in two spatial dimensions. We focus on transitions in the universality class of the dirty 3d XY model. We use a dual model consisting of a single Dirac fermion at zero density coupled to a Chern-Simons gauge field in the presence of a quenched random mass, with or without an unscreened Coulomb interaction. Our calculation is performed in a 1/Nf expansion, where Nf is the number of Dirac fermions. At zeroth order, the model exhibits particle-vortex self-dual electrical transport with σxx (2e)2/h and small, but finite σxy. Corrections of O(1/Nf) due to fluctuations in the Chern-Simons gauge field and disorder produce violations of self-duality. We find these violations to be milder when the Coulomb interaction is present.