Power-law localization in two-dimensional systems Theory and experiment

Abstract

It is shown that all the non-metallic transport phenomena in the weak-disorder limit for small length scales result from a quasi-extended wavefunction φ_E=ψ⁽¹⁾ _ext+ ψ⁽²⁾ _ext/r. For large length scales, φ_E changes into pure power-law states, φ_E = C/r ^S. For S > 1, diffusive transport is predicted with σ_dif ∼T ^S/(S+1). For stronger disorder, S increases and for S < 1, hopping conduction is predicted. In this region the negative magnetoresistance should disappear. Experimental evidence is given for all the above predictions. We also construct a two-parameter scaling function, appropriate to power-law localization, which is in agreement with experiment. We show that all the available data support the existence of power-law localized states which are separated by a mobility edge from exponential localized states.