Failure of single-parameter scaling of wave functions in Anderson localization
Abstract
We show how to use properties of the vectors which are iterated in the transfer-matrix approach to Anderson localization, in order to generate the statistical distribution of electronic wavefunction amplitudes at arbitary distances from the origin of Ld-1 × ∞ disordered systems. For d=1 our approach is shown to reproduce exact diagonalization results available in the literature. In d=2, where strips of width L ≤ 64 sites were used, attempted fits of gaussian (log-normal) forms to the wavefunction amplitude distributions result in effective localization lengths growing with distance, contrary to the prediction from single-parameter scaling theory. We also show that the distributions possess a negative skewness S, which is invariant under the usual histogram-collapse rescaling, and whose absolute value increases with distance. We find 0.15 -S 0.30 for the range of parameters used in our study, .
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