A quantum-dot heat engine operating close to the thermodynamic efficiency limits

Cyclical heat engines are a paradigm of classical thermodynamics, but are impractical for miniaturization because they rely on moving parts. A more recent concept is particle-exchange (PE) heat engines, which uses energy filtering to control a thermally driven particle flow between two heat reservoi...

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Bibliographic Details
Published inarXiv.org
Main Authors Josefsson, Martin, Artis Svilans, Burke, Adam M, Hoffmann, Eric A, Fahlvik, Sofia, Thelander, Claes, Leijnse, Martin, Linke, Heiner
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 17.07.2018
Subjects
Coolers
Efficiency
Energy conversion efficiency
Energy harvesting
Heat engines
Heat exchange
Heat transmission
Maximum power
Miniaturization
Nanowires
Photovoltaic cells
Physics - Mesoscale and Nanoscale Physics
Power efficiency
Predictions
Quantum dots
Solar cells
Thermodynamic efficiency
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Summary:Cyclical heat engines are a paradigm of classical thermodynamics, but are impractical for miniaturization because they rely on moving parts. A more recent concept is particle-exchange (PE) heat engines, which uses energy filtering to control a thermally driven particle flow between two heat reservoirs. As they do not require moving parts and can be realized in solid-state materials, they are suitable for low-power applications and miniaturization. It was predicted that PE engines could reach the same thermodynamically ideal efficiency limits as those accessible to cyclical engines, but this prediction has not been verified experimentally. Here, we demonstrate a PE heat engine based on a quantum dot (QD) embedded into a semiconductor nanowire. We directly measure the engine's steady-state electric power output and combine it with the calculated electronic heat flow to determine the electronic efficiency \(\eta\). We find that at the maximum power conditions, \(\eta\) is in agreement with the Curzon-Ahlborn efficiency and that the overall maximum \(\eta\) is in excess of 70\(\%\) of the Carnot efficiency while maintaining a finite power output. Our results demonstrate that thermoelectric power conversion can, in principle, be achieved close to the thermodynamic limits, with direct relevance for future hot-carrier photovoltaics, on-chip coolers or energy harvesters for quantum technologies.
ISSN:2331-8422
DOI:10.48550/arxiv.1710.00742