Full counting statistics in a disordered free fermion system
Abstract
The Full Counting Statistics (FCS) is studied for a one-dimensional system of non-interacting fermions with and without disorder. For two unbiased site lattices connected at time , the charge variance increases as the natural logarithm of , following the universal expression . Since the static charge variance for a length region is given by , this result reflects the underlying relativistic or conformal invariance and dynamical exponent of the disorder-free lattice. With disorder and strongly localized fermions, we have compared our results to a model with a dynamical exponent , and also a model for entanglement entropy based upon dynamical scaling at the Infinite Disorder Fixed Point (IDFP). The latter scaling, which predicts , appears to better describe the charge variance of disordered 1-d fermions. When a bias voltage is introduced, the behavior changes dramatically and the charge and variance become proportional to and , respectively. The exponent may be related to the critical exponent characterizing spatial/energy fluctuations at the IDFP.
Keywords
Cite
@article{arxiv.1201.3933,
title = {Full counting statistics in a disordered free fermion system},
author = {G. C. Levine and M. J. Bantegui and J. A. Burg},
journal= {arXiv preprint arXiv:1201.3933},
year = {2013}
}
Comments
10 pages, 14 figures; fixed typos; added references; added IDFP scaling based upon reference [1]; added finite bias section; fixed typos