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Main Author: Moreira Jr, E. S.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.06343
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author Moreira Jr, E. S.
author_facet Moreira Jr, E. S.
contents At first glance, the title of this work seems to be improper. And the reason is well known. Since blackbody pressure depends only on temperature, one cannot take the derivative of the thermodynamic quantities with respect to one of them, keeping the other constant. That is, the heat capacity at constant pressure, $C_{P}$, as well as, the coefficient of thermal expansion, $α$, and the isothermal compressibility, $κ_{T}$, are ill-defined quantities. This work will show that when the perfect conducting nature of the walls of a blackbody cavity is taken into account, $C_{P}$, $α$ and $κ_{T}$ are in fact well defined, and they are related by the usual thermodynamic relations, as expected. Two geometries will be considered, namely, a spherical shell and a cubic box. It will be shown that $C_{P}$, $α$ and $κ_{T}$ depend very much on the geometry of the cavity. Issues regarding thermodynamic stability will be addressed, revealing that they also depend on the cavity's geometry. It is argued that these findings may be amenable to experimental verification.
format Preprint
id arxiv_https___arxiv_org_abs_2402_06343
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Blackbody heat capacity at constant pressure
Moreira Jr, E. S.
Statistical Mechanics
High Energy Physics - Theory
Quantum Physics
At first glance, the title of this work seems to be improper. And the reason is well known. Since blackbody pressure depends only on temperature, one cannot take the derivative of the thermodynamic quantities with respect to one of them, keeping the other constant. That is, the heat capacity at constant pressure, $C_{P}$, as well as, the coefficient of thermal expansion, $α$, and the isothermal compressibility, $κ_{T}$, are ill-defined quantities. This work will show that when the perfect conducting nature of the walls of a blackbody cavity is taken into account, $C_{P}$, $α$ and $κ_{T}$ are in fact well defined, and they are related by the usual thermodynamic relations, as expected. Two geometries will be considered, namely, a spherical shell and a cubic box. It will be shown that $C_{P}$, $α$ and $κ_{T}$ depend very much on the geometry of the cavity. Issues regarding thermodynamic stability will be addressed, revealing that they also depend on the cavity's geometry. It is argued that these findings may be amenable to experimental verification.
title Blackbody heat capacity at constant pressure
topic Statistical Mechanics
High Energy Physics - Theory
Quantum Physics
url https://arxiv.org/abs/2402.06343