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Bose Condensate in the D-Dimensional Cas...

Maslov, V. P....

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Bose Condensate in the D-Dimensional Case, in Particular, for D=2. Semiclassical transition to the classical thermodynamics by Maslov, V. P. ( Author )

Content Provider	Lemonjar Open Access
Publisher	Australian National University
Publication Date	21-08-2023
Summary	The number-theoretical problem of partition of an integer corresponds to $D=2$. This problem obeys the Bose--Eeinstein statistics, where repeated terms are admissible in the partition, and to the Fermi--Dirac statistics, where they are inadmissible. The Hougen--Watson P,Z-diagram shows that this problem splits into two cases: the positive pressure domain corresponds to the Fermi system, and the negative, to the Bose system. This analogy can be applied to the van der Waals thermodynamics. The thermodynamic approach is related to four potentials corresponding to the energy, free energy, thermodynamic Gibbs potential, enthalpy. The important notion of de Broglie's wavelength permits passing from particle to wave packet, in particular, to Bose and Fermi distributions. Particles of ideal Bose and Fermi gases and the decay of a boson consisting of two fermions into separate fermions are studied. The case of finitely many particles $N$ of the order of $10^2$ is considered by heuristic considerations like those Fock used to derive the Hartree--Fock equation. The case of $N\ll1$ is studied by Gentile statistics, tropical geometry and nonstandard analysis (Leibnitz differential or monad). A relation for the energy of neutron separation from the atomic nucleus is obtained when the atomic nucleus volume and de Broglie's wavelength are known. The Appendix is author's paper written in 1995.
ISBN	-
Item Type	Article
File Type	pdf
File Size	29.34 KB
Language	English
Subjects	-
Unlimited	MYR 0.01
Total read	-
URL	http://arxiv.org/abs/1207.0019

Citation

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AMA 11th EditionReferences

Maslov, V. P.. Bose Condensate in the D-Dimensional Case, in Particular, for D=2. Semiclassical transition to the classical thermodynamics. Australian National University. August 21, 2023. Accessed November 07, 2024. https://online.provdatabase.com/cite/20130

APA 7th EditionReferences

Maslov, V. P.. (2023). Bose Condensate in the D-Dimensional Case, in Particular, for D=2. Semiclassical transition to the classical thermodynamics. Australian National University. https://online.provdatabase.com/cite/20130

Chicago 17th EditionReferences

HarvardReferences

Maslov, V. P.. (2023). Bose Condensate in the D-Dimensional Case, in Particular, for D=2. Semiclassical transition to the classical thermodynamics. [Online]. Australian National University. Available from: https://online.provdatabase.com/cite/20130. (Accessed 07 November 2024).

Harvard AustraliaReferences

Maslov, V. P., 2023, Bose Condensate in the D-Dimensional Case, in Particular, for D=2. Semiclassical transition to the classical thermodynamics, Australian National University, viewed 07 November 2024, <https://online.provdatabase.com/cite/20130>

MLA 9th EditionWorks Cited

Maslov, V. P.. Bose Condensate in the D-Dimensional Case, in Particular, for D=2. Semiclassical transition to the classical thermodynamics. Australian National University, 2023. PROV Database, https://online.provdatabase.com/cite/20130.

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