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On Entropy Production in the Madelung Fluid and the Role of Bohm’s Potential in Classical Diffusion
Foundations of Physics 46 (7):815-824 (2016)
Abstract
The Madelung equations map the non-relativistic time-dependent Schrödinger equation into hydrodynamic equations of a virtual fluid. While the von Neumann entropy remains constant, we demonstrate that an increase of the Shannon entropy, associated with this Madelung fluid, is proportional to the expectation value of its velocity divergence. Hence, the Shannon entropy may grow due to an expansion of the Madelung fluid. These effects result from the interference between solutions of the Schrödinger equation. Growth of the Shannon entropy due to expansion is common in diffusive processes. However, in the latter the process is irreversible while the processes in the Madelung fluid are always reversible. The relations between interference, compressibility and variation of the Shannon entropy are then examined in several simple examples. Furthermore, we demonstrate that for classical diffusive processes, the “force” accelerating diffusion has the form of the positive gradient of the quantum Bohm potential. Expressing then the diffusion coefficient in terms of the Planck constant reveals the lower bound given by the Heisenberg uncertainty principle in terms of the product between the gas mean free path and the Brownian momentum.Links
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Citations of this work
The Identification of Mean Quantum Potential with Fisher Information Leads to a Strong Uncertainty Relation.Yakov Bloch & Eliahu Cohen - 2022 - Foundations of Physics 52 (6):1-11.
The Common Logic of Quantum Universe—Part I: The Case of Non-relativistic Quantum Mechanics.Massimo Tessarotto & Claudio Cremaschini - 2022 - Foundations of Physics 52 (1):1-38.
References found in this work
Toward a Thermo-hydrodynamic Like Description of Schrödinger Equation via the Madelung Formulation and Fisher Information.Eyal Heifetz & Eliahu Cohen - 2015 - Foundations of Physics 45 (11):1514-1525.
Interpretation of the hydrodynamical formalism of quantum mechanics.Sebastiano Sonego - 1991 - Foundations of Physics 21 (10):1135-1181.
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