Density of quasiparticle states for a two-dimensional disordered system: Metallic, insulating, and critical behavior in the class D thermal quantum Hall effect

Abstract

We investigate numerically the quasiparticle density of states (E) for a two-dimensional, disordered superconductor in which both time-reversal and spin-rotation symmetry are broken. As a generic single-particle description of this class of systems (symmetry class D), we use the Cho-Fisher version of the network model. This has three phases: a thermal insulator, a thermal metal, and a quantized thermal Hall conductor. In the thermal metal we find a logarithmic divergence in (E) as E 0, as predicted from sigma model calculations. Finite size effects lead to superimposed oscillations, as expected from random matrix theory. In the thermal insulator and quantized thermal Hall conductor, we find that (E) is finite at E=0. At the plateau transition between these phases, (E) decreases towards zero as |E| is reduced, in line with the result (E) |E|(1/|E|) derived from calculations for Dirac fermions with random mass.

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