Abstract Quantum dot systems emerge as promising platforms for studying nanoscale thermoelectric effects and quantum fluctuations phenomena. In this work, we investigate thermodynamic performances of a Coulomb-blockaded quantum dot as a quantum heat engine using the quantum master equation approach. By incorporating full counting statistics, we analyze both the average transport properties and current fluctuations in this nanoscale system. We demonstrate that electron-electron interactions significantly enhance the thermoelectric performance, increasing both the output power and energy conversion efficiency. Furthermore, we show that Coulomb interactions suppress current fluctuations while maintaining the validity of the thermodynamic uncertainty relation. Our results provide important insights into the interplay between quantum effects and thermodynamic principles in nanoscale heat engines.
Zhuang et al. (Tue,) studied this question.