Abstract
Heat engines constitute the major building blocks of modern technologies. However, conventional heat engines with higher power yield lesser efficiency and vice versa and respect various power-efficiency trade-off relations. This is also assumed to be true for the engines operating in the quantum regime. Here we show that these relations are not fundamental. We introduce quantum heat engines that deliver maximum power with Carnot efficiency in the one-shot finite-size regime. These engines are composed of working systems with a finite number of quantum particles and are restricted to one-shot measurements. The engines operate in a one-step cycle by letting the working system simultaneously interact with hot and cold baths via semi-local thermal operations. By allowing quantum entanglement between its constituents and, thereby, a coherent transfer of heat from hot to cold baths, the engine implements the fastest possible reversible state transformation in each cycle, resulting in maximum power and Carnot efficiency. Finally, we propose a physically realizable engine using quantum optical systems.
Highlights
Since the beginning of the industrial revolution, heat engines have been playing pivotal roles in shaping modern technologies
For finite-time classical engines, it is known that the maximum power at maximum heat-to-work conversion efficiency is impossible [1]
For quantum engines, where the working systems interacting with the baths are quantum mechanical, the situation is quite different because the quantum uncertainties present in the system further delimit the extractable work in each cycle
Summary
Since the beginning of the industrial revolution, heat engines have been playing pivotal roles in shaping modern technologies. Finite size heat engines, in general, deliver fluctuating efficiency [26,27,30] It is true for power for engines operating with finite-time cycle [36,42]. We introduce quantum heat engines operating in the one-shot finite-size regime and study the power and efficiency of heat-to-work conversion. The engines deliver maximum power, along with Carnot efficiency, purely because the engines allow a coherent transfer of heat from hot to cold baths by establishing quantum entanglement between the working system and the baths, thereby attaining maximum quantum speed for the reversible state transformation in each engine cycle.
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