Related papers: Finite-time quantum measurement cooling beyond the Carnot limit

Finite-time quantum measurement cooling beyond the Carnot limit

URL: http://arxiv.org/abs/2111.12467v2
Date: Fri, 28 Jan 2022 12:18:23 GMT
Title: Finite-time quantum measurement cooling beyond the Carnot limit
Authors: Tong Fu, Jianying Du, Jingyi Chen, Jincan Chen, Chikako Uchiyama, Shanhe Su
Abstract summary: Invasive measurement provides the power to drive the cooling cycle. Measurement-feedback information is capable of moving heat from the cold to hot bath without any work input.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We proposed the finite-time cycle model of a measurement-based quantum cooler, where invasive measurement provides the power to drive the cooling cycle. Such a cooler may be regarded as an alternative thought experiment of Mawell's demon. The measurement-feedback information is capable of moving heat from the cold to hot bath without any work input and even making the maximum coefficient of performance larger than the Carnot limit. The causes that this seemingly paradoxical result does not violate the laws of thermodynamics can be clearly explained through the derivation of a generalized Clausius inequality including the mutual information.

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