Correlation-induced metal-insulator transition in the one-dimensional Anderson model

We study the nature of the electronic states in tight-binding one-dimension al models with long-range correlated disorder. In particular, we study both diagonal and off-diagonal chains. The energies are considered to be in suc h a sequency to describe the trace of a fractional Brownian motion with a s pecified spectral density S(k) proportional to 1/k(alpha). Using a renormal ization group technique, we show that for random on-site energy sequences w ith anti-persistent increments (alpha < 2) all energy eigenstates are expon entially localized. On the other hand, for on-site energy sequences with pe rsistent increments (alpha > 2), the Lyapunov coefficient (inverse localiza tion length) vanishes within a finite range of energy values revealing the presence of an Anderson-like metal-insulator transition. In the case of off -diagonal disorder a phase of delocalized states becomes stable for any alp ha > 1. (C) 1999 Elsevier Science B.V. All rights reserved.