Exact noise and dissipation operators for quantum stochastic thermodynamics

• URL: http://arxiv.org/abs/2504.11938v1
• Date: Wed, 16 Apr 2025 10:16:33 GMT
• Title: Exact noise and dissipation operators for quantum stochastic thermodynamics
• Authors: Stefano Giordano, Fabrizio Cleri, Ralf Blossey,
• Abstract summary: A rigorous formulation of quantum dissipation in conjunction with thermal noise remains a topic of active research.<n>We show that thermal noise at the quantum level manifests as a multidimensional geometric quantization process.<n>Our results advance the understanding of dissipation in quantum systems and provide new insights into nonequilibrium thermodynamics at the quantum scale.
• Score: 0.4123763595394021
• License: http://creativecommons.org/licenses/by-nc-nd/4.0/
• Abstract: The theory of open quantum systems plays a fundamental role in several scientific and technological disciplines, from quantum computing and information science to molecular electronics and quantum thermodynamics. Despite its widespread relevance, a rigorous formulation of quantum dissipation in conjunction with thermal noise remains a topic of active research. In this work, we establish a formal correspondence between classical stochastic thermodynamics, in particular the Fokker-Planck and Klein-Kramers equations, and the quantum master equation. Building on prior studies of multiplicative noise in classical stochastic differential equations, we demonstrate that thermal noise at the quantum level manifests as a multidimensional geometric stochastic process. By applying canonical quantization, we introduce a novel Hermitian dissipation operator that serves as a quantum analogue of classical viscous friction. This operator not only preserves the mathematical rigor of open quantum system dynamics but also allows for a well-defined expression of heat exchange between a system and its environment, enabling the formulation of an alternative quantum equipartition theorem. Our framework ensures a precise energy balance that aligns with the first law of thermodynamics and an entropy balance consistent with the second law. The theoretical formalism is applied to two prototypical quantum systems, the harmonic oscillator and a particle in an infinite potential well, for whom it provides new insights into nonequilibrium thermodynamics at the quantum scale. Our results advance the understanding of dissipation in quantum systems and establish a foundation for future studies on stochastic thermodynamics in the quantum domain.

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