Related papers: A many-particle bosonic quantum Maxwell demon

A many-particle bosonic quantum Maxwell demon

URL: http://arxiv.org/abs/2412.03241v1
Date: Wed, 04 Dec 2024 11:42:48 GMT
Title: A many-particle bosonic quantum Maxwell demon
Authors: Josef Hloušek, Tobias Denzler, Vojtěch Švarc, Miroslav Ježek, Eric Lutz, Radim Filip,
Abstract summary: We report the first experimental realization of a quantum demon in a many-particle photonic setup made of two identical thermal light beams. We show that single-photon measurements combined with feedforward operation may deterministically increase the mean energy of one beam faster than energy fluctuations.
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Abstract: Energy extraction from a measured quantum system is a cornerstone of information thermodynamics as illustrated by Maxwell's demon. The nonequilibrium physics of many-particle systems is additionally strongly influenced by quantum statistics. We here report the first experimental realization of a quantum demon in a many-particle photonic setup made of two identical thermal light beams. We show that single-photon measurements combined with feedforward operation may deterministically increase the mean energy of one beam faster than energy fluctuations, thus improving the thermodynamic stability of the device. We moreover demonstrate that bosonic statistics can enhance the energy output above the classical limit, and further analyze the counterintuitive thermodynamics of the demon using an information-theoretic approach. Our results underscore the pivotal role of many-particle statistics for enhanced energy extraction in quantum thermodynamics.

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