Quantum transmission in disordered insulators: random matrix theory and transverse localization
Abstract
We consider quantum interferences of classically allowed or forbidden electronic trajectories in disordered dielectrics. Without assuming a directed path approximation, we represent a strongly disordered elastic scatterer by its transmission matrix t. We recall how the eigenvalue distribution of t.t can be obtained from a certain ansatz leading to a Coulomb gas analogy at a temperature β-1 which depends on the system symmetries. We recall the consequences of this random matrix theory for quasi--1d insulators and we extend our study to microscopic three dimensional models in the presence of transverse localization. For cubes of size L, we find two regimes for the spectra of t.t as a function of the localization length . For L / ≈ 1 - 5, the eigenvalue spacing distribution remains close to the Wigner surmise (eigenvalue repulsion). The usual orthogonal--unitary cross--over is observed for large magnetic field change B ≈ 0 /2 where 0 denotes the flux quantum. This field reduces the conductance fluctuations and the average log--conductance (increase of ) and induces on a given sample large magneto--conductance fluctuations of typical magnitude similar to the sample to sample fluctuations (ergodic behaviour). When is of the order of the
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