Beyond universal behavior in the one-dimensional chain with random nearest neighbor hopping

Abstract

We study the one-dimensional nearest neighbor tight binding model of electrons with independently distributed random hopping and no on-site potential (i.e. off-diagonal disorder with particle-hole symmetry, leading to sub-lattice symmetry, for each realization). For non-singular distributions of the hopping, it is known that the model exhibits a universal, singular behavior of the density of states (E) 1/|E 3|E|| and of the localization length (E) ||E||, near the band center E = 0. (This singular behavior is also applicable to random XY and Heisenberg spin chains; it was first obtained by Dyson for a specific random harmonic oscillator chain). Simultaneously, the state at E = 0 shows a universal, sub-exponential decay at large distances [ -r/r0 ]. In this study, we consider singular, but normalizable, distributions of hopping, whose behavior at small t is of the form 1/ [t λ+1(1/t) ], characterized by a single, continuously tunable parameter λ > 0. We find, using a combination of analytic and numerical methods, that while the universal result applies for λ > 2, it no longer holds in the interval 0 < λ < 2. In particular, we find that the form of the density of states singularity is enhanced (relative to the Dyson result) in a continuous manner depending on the non-universal parameter λ; simultaneously, the localization length shows a less divergent form at low energies, and ceases to diverge below λ = 1. For λ < 2, the fall-off of the E = 0 state at large distances also deviates from the universal result, and is of the form [-(r/r0)1/λ], which decays faster than an exponential for λ < 1.