Entanglement enhances cooling in microscopic quantum refrigerators

Nicolas Brunner; Marcus Huber; Noah Linden; Sandu Popescu; Ralph Silva; Paul Skrzypczyk

doi:10.1103/PhysRevE.89.032115

Entanglement enhances cooling in microscopic quantum refrigerators

Nicolas Brunner, Marcus Huber, Noah Linden, Sandu Popescu, Ralph Silva, Paul Skrzypczyk

Departamento de Física

Producción científica: Contribución a una revista › Artículo › Investigación › revisión exhaustiva

185 Citas (Scopus)

Resumen

Small self-contained quantum thermal machines function without external source of work or control but using only incoherent interactions with thermal baths. Here we investigate the role of entanglement in a small self-contained quantum refrigerator. We first show that entanglement is detrimental as far as efficiency is concerned - fridges operating at efficiencies close to the Carnot limit do not feature any entanglement. Moving away from the Carnot regime, we show that entanglement can enhance cooling and energy transport. Hence, a truly quantum refrigerator can outperform a classical one. Furthermore, the amount of entanglement alone quantifies the enhancement in cooling. © 2014 American Physical Society.

Idioma original	Inglés
Número de artículo	032115
Publicación	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volumen	89
N.º	3
DOI	https://doi.org/10.1103/PhysRevE.89.032115
Estado	Publicada - 13 mar 2014

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title = "Entanglement enhances cooling in microscopic quantum refrigerators",

abstract = "Small self-contained quantum thermal machines function without external source of work or control but using only incoherent interactions with thermal baths. Here we investigate the role of entanglement in a small self-contained quantum refrigerator. We first show that entanglement is detrimental as far as efficiency is concerned - fridges operating at efficiencies close to the Carnot limit do not feature any entanglement. Moving away from the Carnot regime, we show that entanglement can enhance cooling and energy transport. Hence, a truly quantum refrigerator can outperform a classical one. Furthermore, the amount of entanglement alone quantifies the enhancement in cooling. {\textcopyright} 2014 American Physical Society.",

author = "Nicolas Brunner and Marcus Huber and Noah Linden and Sandu Popescu and Ralph Silva and Paul Skrzypczyk",

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AU - Huber, Marcus

AU - Linden, Noah

AU - Popescu, Sandu

AU - Silva, Ralph

AU - Skrzypczyk, Paul

PY - 2014/3/13

Y1 - 2014/3/13

N2 - Small self-contained quantum thermal machines function without external source of work or control but using only incoherent interactions with thermal baths. Here we investigate the role of entanglement in a small self-contained quantum refrigerator. We first show that entanglement is detrimental as far as efficiency is concerned - fridges operating at efficiencies close to the Carnot limit do not feature any entanglement. Moving away from the Carnot regime, we show that entanglement can enhance cooling and energy transport. Hence, a truly quantum refrigerator can outperform a classical one. Furthermore, the amount of entanglement alone quantifies the enhancement in cooling. © 2014 American Physical Society.

AB - Small self-contained quantum thermal machines function without external source of work or control but using only incoherent interactions with thermal baths. Here we investigate the role of entanglement in a small self-contained quantum refrigerator. We first show that entanglement is detrimental as far as efficiency is concerned - fridges operating at efficiencies close to the Carnot limit do not feature any entanglement. Moving away from the Carnot regime, we show that entanglement can enhance cooling and energy transport. Hence, a truly quantum refrigerator can outperform a classical one. Furthermore, the amount of entanglement alone quantifies the enhancement in cooling. © 2014 American Physical Society.

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Entanglement enhances cooling in microscopic quantum refrigerators

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