Statistical Approach to Quantum Chaotic Ratchets
Abstract
The quantum ratchet effect in fully chaotic systems is approached by studying, for the first time, \emph{statistical} properties of the ratchet current over well-defined sets of initial states. Natural initial states in a semiclassical regime are those that are \emph{phase-space uniform} with the \emph{maximal possible} resolution of one Planck cell. General arguments in this regime, for quantum-resonance values of a scaled Planck constant , predict that the distribution of the current over all such states is a zero-mean Gaussian with variance , where is the chaotic-diffusion coefficient. This prediction is well supported by extensive numerical evidence. The average strength of the effect, measured by the variance above, is \emph{significantly larger} than that for the usual momentum states and other states. Such strong effects should be experimentally observable.
Cite
@article{arxiv.1003.2995,
title = {Statistical Approach to Quantum Chaotic Ratchets},
author = {Itzhack Dana},
journal= {arXiv preprint arXiv:1003.2995},
year = {2010}
}
Comments
REVTEX4, 13 pages, 4 figures