Many-body Correlation Effect on Mesoscopic Charge Relaxation

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, Rq(ω=0) = h/4e2 ensured by the Korringa-Shiba rule whereas the interpretation of the quantum capacitance Cq in terms of the density of states fails when strong correlations are present. The AC resistance Rq(ω) shows huge peaks (with values larger than h/4e2) at ω ≈ *, where * is the renormalized level broadening. These peaks are merged to a single one at ω=0 when a finite Zeeman field is applied comparable to *. The observed features of Rq, 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.