Thermodynamic uncertainty relation in slowly driven quantum heat engines

Thermodynamic Uncertainty Relations express a trade-off between precision, defined as the noise-to-signal ratio of a generic current, and the amount of associated entropy production. These results have deep consequences for autonomous heat engines operating at steady-state, imposing an upper bound for their efficiency in terms of the power yield and its fluctuations. In the present manuscript we analyze a different class of heat engines, namely those which are operating in the periodic slow-driving regime, and we show that a tighter TUR-bound holds. Remarkably, this TUR is influenced by a genuinely quantum contribution, which leads to an increase in the power fluctuations. This allows us to prove that quantum effects, for slow driving, reduce engine efficiency relative to the average power and reliability. We finally illustrate our findings in the experimentally relevant model of a single-ion heat engine.