Conductance of 1D quantum wires with anomalous electron-wavefunction localization

Abstract

We study the statistics of the conductance g through one-dimensional disordered systems where electron wavefunctions decay spatially as || (-λ rα) for 0 <α <1, λ being a constant. In contrast to the conventional Anderson localization where || (-λ r) and the conductance statistics is determined by a single parameter: the mean free path, here we show that when the wave function is anomalously localized (α <1) the full statistics of the conductance is determined by the average < g> and the power α. Our theoretical predictions are verified numerically by using a random hopping tight-binding model at zero energy, where due to the presence of chiral symmetry in the lattice there exists anomalous localization; this case corresponds to the particular value α =1/2. To test our theory for other values of α, we introduce a statistical model for the random hopping in the tight binding Hamiltonian.