Current deformation and quantum inductance in mesoscopic capacitors

Abstract

We present a theoretical analysis of low frequency dynamics of a single-channel mesoscopic capacitor, which is composed by a quantum dot connected to an electron reservoir via a single quantum channel. At low frequencies, it is known that the Wigner-Smith delay time τW plays a dominant role and it can be interpreted as the time delay between the current leaving the dot and the current entering the dot. At higher frequencies, we find that another characteristic time τS can also be important. It describes the deformation of the leaving current to the entering one and hence can be referred as the deformation time. At sufficient low temperatures, the deformation time τS can be approximated from the second-order derivative of τW via a simple relation τ"W/τ3S=24/2. As the temperature increases, this relation breaks down and one has instead τ"W/τ3S 0 in the high temperature limit. We further show that the deformation time τS can have a pronounced influence on the quantum inductance Lq of the mesoscopic capacitor, leading to features different from the ones of the quantum capacitance. The most striking one is that Lq can change its sign as the temperature increases: It can go from positive values at low temperatures to large negative values at high temperatures. The above results demonstrate the importance of the deformation time τS on the ac conductance of the mesoscopic capacitor.