Gert-Ludwig Ingold, Andre Wobst, Christian Aulbach, Peter Hänggi
Published 2002-05-02Version 1
In the one-dimensional Anderson model the eigenstates are localized for arbitrarily small amounts of disorder. In contrast, the Harper model with its quasiperiodic potential shows a transition from extended to localized states. The difference between the two models becomes particularly apparent in phase space where Heisenberg's uncertainty relation imposes a finite resolution. Our analysis points to the relevance of the coupling between momentum eigenstates at weak potential strength for the delocalization of a quantum particle.
Comments: 7 pages, 2 figures, EPL class included
Journal: Eur. Phys. J. B 30, 175 (2002)
Delocalization of relativistic Dirac particles in disordered one-dimensional systems and its implementation with cold atoms
Statistical properties of phases and delay times of the one-dimensional Anderson model with one open channel
Parametrization of the transfer matrix: for one-dimensional Anderson model with diagonal disorder
