English

A Lloyd-model generalization: Conductance fluctuations in one-dimensional disordered systems

Disordered Systems and Neural Networks 2016-04-05 v1

Abstract

We perform a detailed numerical study of the conductance GG through one-dimensional (1D) tight-binding wires with on-site disorder. The random configurations of the on-site energies ϵ\epsilon of the tight-binding Hamiltonian are characterized by long-tailed distributions: For large ϵ\epsilon, P(ϵ)1/ϵ1+αP(\epsilon)\sim 1/\epsilon^{1+\alpha} with α(0,2)\alpha\in(0,2). Our model serves as a generalization of 1D Lloyd's model, which corresponds to α=1\alpha=1. First, we verify that the ensemble average lnG\left\langle -\ln G\right\rangle is proportional to the length of the wire LL for all values of α\alpha, providing the localization length ξ\xi from lnG=2L/ξ\left\langle-\ln G\right\rangle=2L/\xi. Then, we show that the probability distribution function P(G)P(G) is fully determined by the exponent α\alpha and lnG\left\langle-\ln G\right\rangle. In contrast to 1D wires with standard white-noise disorder, our wire model exhibits bimodal distributions of the conductance with peaks at G=0G=0 and 11. In addition, we show that P(lnG)P(\ln G) is proportional to GβG^\beta, for G0G\to 0, with βα/2\beta\le\alpha/2, in agreement to previous studies.

Keywords

Cite

@article{arxiv.1604.00692,
  title  = {A Lloyd-model generalization: Conductance fluctuations in one-dimensional disordered systems},
  author = {J. A. Mendez-Bermudez and A. J. Martinez-Mendoza and V. A. Gopar and I. Varga},
  journal= {arXiv preprint arXiv:1604.00692},
  year   = {2016}
}

Comments

5 pages, 5 figures

R2 v1 2026-06-22T13:24:14.208Z