Kang-Hun Ahn, Pritiraj Mohanty
Published 2000-11-08Version 1
The electron dephasing time $\tau_{\phi}$ in a diffusive quantum dot is calculated by considering the interaction between the electron and dynamical defects, modelled as two-level system. Using the standard tunneling model of glasses, we obtain a linear temperature dependence of $1/\tau_{\phi}$, consistent with the experimental observation. However, we find that, in order to obtain dephasing times on the order of nanoseconds, the number of two-level defects needs to be substantially larger than the typical concentration in glasses. We also find a finite system-size dependence of $\tau_{\phi}$, which can be used to probe the effectiveness of surface-aggregated defects.
Comments: two-column 9 pages
Properties of low-lying states in a diffusive quantum dot and Fock-space localization
Heat transport through a two-level system under continuous quantum measurement
Dynamics of a two-level system strongly coupled to a high-frequency quantum oscillator
