超越标准第二定律的相关量子机器

Milton Aguilar, Eric Lutz
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引用次数: 0

摘要

热力学定律极大地限制了热机的性能。标准热力学最初是针对不相关的微观系统而开发的,但对于与其环境相关的微观系统却不适用。我们在此推导出适用于任意、时间周期性、开放系统的精确广义量子热力学定律,这些定律考虑了所有参与方之间可能存在的相关性。我们证明了发动机运行的两种基本模式:一种是通常的热模式,即热量转化为功;另一种是新颖的非热模式,即从熵资源(如系统与水浴的相关性)中提取功。在后一种情况下,量子引擎的效率不受通常的卡诺公式约束。我们的结果为确定相关微观热器件的效率提供了统一的形式主义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Correlated quantum machines beyond the standard second law
The laws of thermodynamics strongly restrict the performance of thermal machines. Standard thermodynamics, initially developed for uncorrelated macroscopic systems, does not hold for microscopic systems correlated with their environments. We here derive exact generalized laws of quantum thermodynamics for arbitrary, time-periodic, open systems that account for all possible correlations between all involved parties. We demonstrate the existence of two basic modes of engine operation: the usual thermal case, where heat is converted into work, and a novel athermal regime, where work is extracted from entropic resources, such as system-bath correlations. In the latter regime, the efficiency of a quantum engine is not bounded by the usual Carnot formula. Our results provide a unified formalism to determine the efficiency of correlated microscopic thermal devices.
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