Gibbs' paradox and black-hole entropy

A. Eckart; A. Ghosh; B.M. Casper; C. Kiefer; C. Kiefer; C. Kiefer; C. Rovelli; C. Vaz; Claus Kiefer; D.N. Page; E. Joos; G. Gour; Gerhard Kolland; H.D. Zeh; H.D. Zeh; J.A. Wheeler; J.D. Bekenstein; K.A. Meissner; K.G. Denbigh; L. Bombelli; M. Cramer; M. Domagala; M. Srednicki; M.M. Akbar; O. Stern; S. Das; S.W. Hawking; V. Ferrari; V.P. Frolov

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Gibbs' paradox and black-hole entropy

Authors: A. Eckart
A. Ghosh
B.M. Casper
C. Kiefer
C. Kiefer
C. Kiefer
C. Rovelli
C. Vaz
Claus Kiefer
D.N. Page
E. Joos
G. Gour
Gerhard Kolland
H.D. Zeh
H.D. Zeh
J.A. Wheeler
J.D. Bekenstein
K.A. Meissner
K.G. Denbigh
L. Bombelli
M. Cramer
M. Domagala
M. Srednicki
M.M. Akbar
O. Stern
S. Das
S.W. Hawking
V. Ferrari
V.P. Frolov
Publication date: 4 July 2007
Publisher: 'Springer Science and Business Media LLC'
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Abstract

In statistical mechanics Gibbs' paradox is avoided if the particles of a gas are assumed to be indistinguishable. The resulting entropy then agrees with the empirically tested thermodynamic entropy up to a term proportional to the logarithm of the particle number. We discuss here how analogous situations arise in the statistical foundation of black-hole entropy. Depending on the underlying approach to quantum gravity, the fundamental objects to be counted have to be assumed indistinguishable or not in order to arrive at the Bekenstein--Hawking entropy. We also show that the logarithmic corrections to this entropy, including their signs, can be understood along the lines of standard statistical mechanics. We illustrate the general concepts within the area quantization model of Bekenstein and Mukhanov.Comment: Contribution to Mashhoon festschrift, 13 pages, 4 figure

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