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Main Authors: Sathe, Pratik, García-Pintos, Luis Pedro, Caravelli, Francesco
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.11974
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author Sathe, Pratik
García-Pintos, Luis Pedro
Caravelli, Francesco
author_facet Sathe, Pratik
García-Pintos, Luis Pedro
Caravelli, Francesco
contents The Heisenberg uncertainty relation, which links the uncertainties of the position and momentum of a particle, has an important footprint on the quantum behavior of a physical system. Analogous to this principle, we propose that thermodynamic currents associated with work, heat, and internal energy satisfy their own uncertainty relations. To formalize this idea, we represent these currents by well-defined Hermitian operators, constructed so that their expectation values match the corresponding average currents. Because these operators generally do not commute, the resulting quantum currents differ fundamentally from their classical counterparts. Using the Robertson-Schrödinger uncertainty relation, we derive various uncertainty relations that link different thermodynamic flows. We further illustrate this approach by applying it to quantum batteries, where we derive an energy-power uncertainty relationship and show how measurements affect the fluctuations.
format Preprint
id arxiv_https___arxiv_org_abs_2406_11974
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Quantum Uncertainty Relations for Thermodynamic Energy Flows
Sathe, Pratik
García-Pintos, Luis Pedro
Caravelli, Francesco
Quantum Physics
The Heisenberg uncertainty relation, which links the uncertainties of the position and momentum of a particle, has an important footprint on the quantum behavior of a physical system. Analogous to this principle, we propose that thermodynamic currents associated with work, heat, and internal energy satisfy their own uncertainty relations. To formalize this idea, we represent these currents by well-defined Hermitian operators, constructed so that their expectation values match the corresponding average currents. Because these operators generally do not commute, the resulting quantum currents differ fundamentally from their classical counterparts. Using the Robertson-Schrödinger uncertainty relation, we derive various uncertainty relations that link different thermodynamic flows. We further illustrate this approach by applying it to quantum batteries, where we derive an energy-power uncertainty relationship and show how measurements affect the fluctuations.
title Quantum Uncertainty Relations for Thermodynamic Energy Flows
topic Quantum Physics
url https://arxiv.org/abs/2406.11974