Theory of Disorder-Induced Half-Integer Thermal Hall Conductance

Abstract

Electrons that are confined to a single Landau level in a two dimensional electron gas realize the effects of strong electron-electron repulsion in its purest form. The kinetic energy of individual electrons is completely quenched and all physical properties are dictated solely by many-body effects. A remarkable consequence is the emergence of new quasiparticles with fractional charge and exotic quantum statistics of which the most exciting ones are non-Abelian quasiparticles. A non-integer quantized thermal Hall conductance xy (in units of temperature times the universal constant π2 kB2 /3 h; h is the Planck constant and kB the Boltzmann constant) necessitates the existence of such quasiparticles. It has been predicted, and verified numerically, that such states are realized in the clean half-filled first Landau level of electrons with Coulomb repulsion, with xy being either 3/2 or 7/2. Excitingly, a recent experiment has indeed observed a half-integer value, which was measured, however, to be xy=5/2. We resolve this contradiction within a picture where smooth disorder results in the formation of mesoscopic puddles with locally xy=3/2 or 7/2. Interactions between these puddles generate a coherent macroscopic state, which is reflected in an extended plateau with quantized xy=5/2. The topological properties of quasiparticles at large distances are determined by the macroscopic phase, and not by the microscopic puddle where they reside. In principle, the same mechanism might also allow non-Abelian quasiparticles to emerge from a system comprised of microscopic Abelian puddles.