Dephasing and Dynamic Localization in Quantum Dots
arXiv:cond-mat/0312316 · doi:10.1007/1-4020-2193-3_6
Abstract
The effects of dynamic localization in a solid-state system -- a quantum dot -- are considered. The theory of weak dynamic localization is developed for non-interacting electrons in a closed quantum dot under arbitrary time-dependent perturbation and its equivalence to the theory of weak Anderson localization is demonstrated. The dephasing due to inelastic electron scattering is shown to destroy the dynamic localization in a closed quantum dot leading to the classical energy absorption at times much greater than the inelastic scattering time. Finally a realistic case of a dot weakly connected to leads is studied and it is shown that the dynamic localization may lead to a drastic change of the shape of the Coulomb blockade peak in the dc conductance vs the gate voltage.
24 pages, 7 figures, Proceeding of the NATO Conference "Fundamental Problems of Mesoscopic Physics: Interaction and Decoherence.", Granada (Spain)