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Fundamental thermodynamical equation of a self-gravitating system

2 Pith papers cite this work. Polarity classification is still indexing.

2 Pith papers citing it
abstract

The features of the fundamental thermodynamical relation (expressing entropy as function of state variables) that arise from the self-gravitating character of a system are analyzed. The models studied include not only a spherically symmetric hot matter shell with constant particle number but also a black hole characterized by a general thermal equation of state. These examples illustrate the formal structure of thermodynamics developed by Callen as applied to a gravitational configuration as well as the phenomenological manner in which Einstein equations largely determine the thermodynamical equations of state. We consider in detail the thermodynamics and quasi-static collapse of a self-gravitating shell. This includes a discussion of intrinsic stability for a one-parameter family of thermal equations of state and the interpretation of the Bekenstein bound. The entropy growth associated with a collapsing sequence of equilibrium states of a shell is computed under different boundary conditions in the quasi-static approximation and compared with black hole entropy. Although explicit expressions involve empirical coefficients, these are constrained by physical conditions of thermodynamical origin. The absence of a Gibbs-Duhem relation and the associated scaling laws for self-gravitating matter systems are presented.

fields

hep-th 2

years

2026 2

verdicts

UNVERDICTED 2

representative citing papers

As Cold as a Black Hole: Extended Photon Spheres

hep-th · 2026-06-29 · unverdicted · novelty 5.0

A necessary and sufficient condition for thermodynamic mimicry of Schwarzschild black holes is satisfied by a one-parameter family of self-similar systems including hillingar black holes, stiffest stars, and frozen stars, derived from photon-sphere control of junction conditions and the TOV equation

citing papers explorer

Showing 2 of 2 citing papers.

  • As Cold as a Black Hole: Extended Photon Spheres hep-th · 2026-06-29 · unverdicted · none · ref 54 · internal anchor

    A necessary and sufficient condition for thermodynamic mimicry of Schwarzschild black holes is satisfied by a one-parameter family of self-similar systems including hillingar black holes, stiffest stars, and frozen stars, derived from photon-sphere control of junction conditions and the TOV equation

  • On Black Holes Surrounded by Radiation II: Thermodynamics hep-th · 2026-06-29 · unverdicted · none · ref 28 · internal anchor

    Hillingar black holes thermodynamically mimic ordinary black holes of mass M, sharing temperature and entropy under thermal equilibrium.