Nonadiabatic particle and energy pump at strong system-reservoir coupling

TL;DR

This paper investigates a quantum dot-based nonadiabatic pump that uses synchronized parameter variations to efficiently transfer electrons and energy, analyzing its performance and limitations in strong coupling regimes.

Contribution

It introduces a four-stroke operating protocol for quantum pumps that enhances energy transfer and performance in strong coupling regimes, with detailed analysis of energy dynamics.

Findings

The four-stroke protocol improves net energy and electron transfer.

Performance declines in weak coupling regimes due to reverse energy flow.

Increasing energy charging duration boosts output but raises energy costs.

Abstract

We study the dynamics of electron and energy currents in a nonadiabatic pump. The pump is a quantum dot nanojunction with time-varying gate potential and tunnel couplings to the leads. The leads are unbiased and maintained at the same temperature and chemical potential. We find that synchronized variations of the gate and tunnel couplings can pump electrons and energy from the left to the right lead. Inspired by quantum heat engines, we devise a four-stroke operating protocol that can optimally pump energy and hence, we investigate energy transfer and the coefficient of performance of the device. We compare our device to a two-stroke pump and find that the latter's lower performance is due to the bi-directional flow of energy currents resulting in low net energy currents. The performance of our four-stroke pump can be improved, up to a point, by increasing the net energy carried by the pumped electrons through energy charging via the gate potential. This is achieved by increasing the durations of energy charging and discharging strokes in the pump's protocol. However, despite the large energy output for long charging and discharging strokes, the energy required to maintain the strokes become large too resulting in a stagnant pump performance. Our pump operates effectively only in the strong lead coupling regime and becomes a dud in the weak coupling regime due to the net output energy flowing in the reverse direction. We use nonequilibirum Green's functions techniques to calculate the currents and capture the effects of strong lead-channel coupling exactly while simultaneously incorporating three time-varying parameters. Results from our work could aid in the design of high-performance quantum pumps.