Exponential sensitivity to dephasing of electrical conduction through a quantum dot
arXiv:cond-mat/0407526 · doi:10.1103/PhysRevLett.93.186806
Abstract
According to random-matrix theory, interference effects in the conductance of a ballistic chaotic quantum dot should vanish $\propto(Ï_Ï/Ï_{D})^{p}$ when the dephasing time $Ï_Ï$ becomes small compared to the mean dwell time $Ï_{D}$. Aleiner and Larkin have predicted that the power law crosses over to an exponential suppression $\propto\exp(-Ï_{E}/Ï_Ï)$ when $Ï_Ï$ drops below the Ehrenfest time $Ï_{E}$. We report the first observation of this crossover in a computer simulation of universal conductance fluctuations. Their theory also predicts an exponential suppression $\propto\exp(-Ï_{E}/Ï_{D})$ in the absence of dephasing -- which is not observed. We show that the effective random-matrix theory proposed previously for quantum dots without dephasing explains both observations.
4 pages, 4 figures