Thermoelectric performance of a driven double quantum dot

TL;DR

This study explores the thermoelectric capabilities of a driven double quantum dot, demonstrating quantized heat and charge transport at low modulation frequencies, with potential for efficient heat transfer and work extraction.

Contribution

It introduces a detailed analysis of heat and charge quantization in a driven double quantum dot, accounting for dissipative effects and finite-frequency limitations.

Findings

Quantized heat and charge currents at low modulation frequencies

Heat transfer can occur against a temperature gradient

Charge pump efficiency can reach up to 70% of the ideal

Abstract

In this paper we investigate the thermoelectric performance of a double-dot device driven by time-dependently modulated gate voltages. We show that if the modulation frequency {\Omega} is sufficiently small, not only quantized charge pumping can be realized, but also the heat current flowing in the leads is quantized and exhibits plateaux in units of kB T ln2 {\Omega}/2{\pi}. The factor ln2 stems from the degeneracy of the double-dot states involved into transport. This opens the possibility of using the pumping cycle to transfer heat against a temperature gradient or to extract work from a hot reservoir with Carnot efficiency. However, the performance of a realistic device is limited by dissipative effects due to leakage currents and finite-frequency operation, which we take into account rigorously by means of a generalized master equation approach in the regime where the double dot is weakly coupled to the leads. We show that despite these effects, the efficiency of a double-dot charge pump performing work against a dc-source can reach of up to 70% of the ideal value.