Many-body Correlation Effect on Mesoscopic Charge Relaxation
arXiv:1101.0468 · doi:10.1103/PhysRevB.83.201304
Abstract
We investigate in a nonperturbative way the dynamics of a correlated quantum capacitor. We find that the many-body correlations do not disturb the universal low-frequency relaxation resistance per channel, $R_q(Ï=0) = h/4e^2$ ensured by the Korringa-Shiba rule whereas the interpretation of the quantum capacitance $C_q$ in terms of the density of states fails when strong correlations are present. The AC resistance $R_q(Ï)$ shows huge peaks (with values larger than $h/4e^2$) at $\hbarÏ\approx \pm Î^*$, where $Î^*$ is the renormalized level broadening. These peaks are merged to a single one at $Ï=0$ when a finite Zeeman field is applied comparable to $Î^*$. The observed features of $R_q$, being most evident in the Kondo regime, are attributed to the generation of particle-hole excitations in the contacts accomplished by spin-flip processes in the dot.
5 pages, 4 figures