Symmetry aspects in an ideal Bose gas at thermal equilibrium

• URL: http://arxiv.org/abs/2410.10893v1
• Date: Sat, 12 Oct 2024 08:55:34 GMT
• Title: Symmetry aspects in an ideal Bose gas at thermal equilibrium
• Authors: Alexej Schelle,
• Abstract summary: It is possible to explain certain new fundamental symmetry aspects of ideal and very weakly interacting Bose gases. The propagation of one-directional time arises from the pre-defined and equivalent convergence of independent quantum fields. It is shown that Glauber's coherent states are related to the definition of the quantized field.
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• Abstract: The theory of ideal gases is supplemented by a numerical quantum field description with a two-dimensional non-local order parameter that allows the modeling of wave-like atomic correlations and interference effects in the limit of low atomic densities. From the present model, it is possible to explain certain new fundamental symmetry aspects of ideal and very weakly interacting Bose gases, like the forward propagation of time and the relation to the breaking and preservation of phase gauge symmetry in solids. In the present formalism, the propagation of one-directional time arises from the pre-defined and equivalent convergence of independent quantum fields towards the Boltzmann equilibrium, and it is shown that Glauber's coherent states are related to the definition of the quantized field. As a direct consequence of thermal equilibrium, the present model describes spontaneous symmetry breaking, which is originally known only from the formal definition of a specific gauge field from Elizur's theorem for local gauge fields, as a continuous physical rather than a purely formal mathematical process.

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