de Broglie Normal Modes in the Madelung Fluid

Eyal Heifetz; Anirban Guha; Leo Maas

doi:10.1007/s10701-023-00676-z

de Broglie Normal Modes in the Madelung Fluid

Eyal Heifetz, Anirban Guha, Leo Maas

School of the Environment and Earth Sciences

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

In an attempt to explore further the Madelung fluid-like representation of quantum mechanics, we derive the small perturbation equations of the fluid with respect to its basic states. The latter are obtained from the Madelung transform of the Schrödinger equation eigenstates. The fundamental eigenstates of de Broglie monochromatic matter waves are then shown to be mapped into the simple basic states of a fluid with constant density and velocity, where the latter is the de Broglie group velocity. The normal modes with respect to these basic states are derived and found to also satisfy the de Broglie dispersion relation. Despite being dispersive waves, their propagation mechanism is equivalent to that of sound waves in a classical ideal adiabatic gas. We discuss the physical interpretation of these results.

Original language	English
Article number	35
Journal	Foundations of Physics
Volume	53
Issue number	2
DOIs	https://doi.org/10.1007/s10701-023-00676-z
State	Published - Apr 2023

Keywords

De Broglie matter waves
Madelung fluid
Normal modes

All Science Journal Classification (ASJC) codes

Philosophy
General Physics and Astronomy
History and Philosophy of Science

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10.1007/s10701-023-00676-z

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abstract = "In an attempt to explore further the Madelung fluid-like representation of quantum mechanics, we derive the small perturbation equations of the fluid with respect to its basic states. The latter are obtained from the Madelung transform of the Schr{\"o}dinger equation eigenstates. The fundamental eigenstates of de Broglie monochromatic matter waves are then shown to be mapped into the simple basic states of a fluid with constant density and velocity, where the latter is the de Broglie group velocity. The normal modes with respect to these basic states are derived and found to also satisfy the de Broglie dispersion relation. Despite being dispersive waves, their propagation mechanism is equivalent to that of sound waves in a classical ideal adiabatic gas. We discuss the physical interpretation of these results.",

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AU - Guha, Anirban

AU - Maas, Leo

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N2 - In an attempt to explore further the Madelung fluid-like representation of quantum mechanics, we derive the small perturbation equations of the fluid with respect to its basic states. The latter are obtained from the Madelung transform of the Schrödinger equation eigenstates. The fundamental eigenstates of de Broglie monochromatic matter waves are then shown to be mapped into the simple basic states of a fluid with constant density and velocity, where the latter is the de Broglie group velocity. The normal modes with respect to these basic states are derived and found to also satisfy the de Broglie dispersion relation. Despite being dispersive waves, their propagation mechanism is equivalent to that of sound waves in a classical ideal adiabatic gas. We discuss the physical interpretation of these results.

AB - In an attempt to explore further the Madelung fluid-like representation of quantum mechanics, we derive the small perturbation equations of the fluid with respect to its basic states. The latter are obtained from the Madelung transform of the Schrödinger equation eigenstates. The fundamental eigenstates of de Broglie monochromatic matter waves are then shown to be mapped into the simple basic states of a fluid with constant density and velocity, where the latter is the de Broglie group velocity. The normal modes with respect to these basic states are derived and found to also satisfy the de Broglie dispersion relation. Despite being dispersive waves, their propagation mechanism is equivalent to that of sound waves in a classical ideal adiabatic gas. We discuss the physical interpretation of these results.

KW - De Broglie matter waves

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JF - Foundations of Physics

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M1 - 35

ER -

de Broglie Normal Modes in the Madelung Fluid

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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