Diagrammatic Approach for the High-Temperature Regime of Quantum Hall Transitions

Abstract

We use a general diagrammatic formalism based on a local conductivity approach to compute electronic transport in continuous media with long-range disorder, in the absence of quantum interference effects. The method allows us then to investigate the interplay of dissipative processes and random drifting of electronic trajectories in the high-temperature regime of quantum Hall transitions. We obtain that the longitudinal conductance σxx scales with an exponent =0.7670.002 in agreement with the value =10/13 conjectured from analogies to classical percolation. We also derive a microscopic expression for the temperature-dependent peak value of σxx, useful to extract from experiments.