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Main Authors: Bhattacharjee, Budhaditya, Ray, Rohit Kishan, Šafránek, Dominik
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.05054
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author Bhattacharjee, Budhaditya
Ray, Rohit Kishan
Šafránek, Dominik
author_facet Bhattacharjee, Budhaditya
Ray, Rohit Kishan
Šafránek, Dominik
contents The mixing of two different gases is one of the most common natural phenomena, with applications ranging from CO$_2$ capture to water purification. Traditionally, mixing is analyzed in the context of local thermal equilibrium, where systems exchange energy with a heat bath. Here, we study mixing in an isolated system with potentially non-equilibrium initial states, characterized solely by macroscopic observables. We identify the entropy of mixing as a special case of observational entropy within an observer-dependent framework, where both entropy and extractable work depend on the resolution of measurement. This approach naturally resolves the Gibbs mixing paradox in quantum systems: while an observer experiences a discontinuous increase in entropy upon learning of the existence of two particle types, this knowledge does not provide an advantage in work extraction if the types of particles remain operationally indistinguishable in their measurements. Finally, we derive a Landauer-like bound on the difference in energy extracted by two observers, where an "observational temperature" emerges, determined by the accessible information. These results provide a foundation for rigorously determining the energy required to unmix in non-equilibrium settings and extend beyond quantum systems, offering insights into the thermodynamics of isolated classical gases.
format Preprint
id arxiv_https___arxiv_org_abs_2507_05054
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Work and entropy of mixing in isolated quantum systems
Bhattacharjee, Budhaditya
Ray, Rohit Kishan
Šafránek, Dominik
Quantum Physics
Quantum Gases
Statistical Mechanics
The mixing of two different gases is one of the most common natural phenomena, with applications ranging from CO$_2$ capture to water purification. Traditionally, mixing is analyzed in the context of local thermal equilibrium, where systems exchange energy with a heat bath. Here, we study mixing in an isolated system with potentially non-equilibrium initial states, characterized solely by macroscopic observables. We identify the entropy of mixing as a special case of observational entropy within an observer-dependent framework, where both entropy and extractable work depend on the resolution of measurement. This approach naturally resolves the Gibbs mixing paradox in quantum systems: while an observer experiences a discontinuous increase in entropy upon learning of the existence of two particle types, this knowledge does not provide an advantage in work extraction if the types of particles remain operationally indistinguishable in their measurements. Finally, we derive a Landauer-like bound on the difference in energy extracted by two observers, where an "observational temperature" emerges, determined by the accessible information. These results provide a foundation for rigorously determining the energy required to unmix in non-equilibrium settings and extend beyond quantum systems, offering insights into the thermodynamics of isolated classical gases.
title Work and entropy of mixing in isolated quantum systems
topic Quantum Physics
Quantum Gases
Statistical Mechanics
url https://arxiv.org/abs/2507.05054