Abstract
There are a number of similarities between black-hole physics and thermodynamics. Most striking is the similarity in the behaviors of black-hole area and of entropy: Both quantities tend to increase irreversibly. In this paper we make this similarity the basis of a thermodynamic approach to black-hole physics. After a brief review of the elements of the theory of information, we discuss black-hole physics from the point of view of information theory. We show that it is natural to introduce the concept of black-hole entropy as the measure of information about a black-hole interior which is inaccessible to an exterior observer. Considerations of simplicity and consistency, and dimensional arguments indicate that the black-hole entropy is equal to the ratio of the black-hole area to the square of the Planck length times a dimensionless constant of order unity. A different approach making use of the specific properties of Kerr black holes and of concepts from information theory leads to the same conclusion, and suggests a definite value for the constant. The physical content of the concept of black-hole entropy derives from the following generalized version of the second law: When common entropy goes down a black hole, the common entropy in the black-hole exterior plus the black-hole entropy never decreases. The validity of this version of the second law is supported by an argument from information theory as well as by several examples.
Keywords
PhysicsBlack hole thermodynamicsWhite holeBlack hole (networking)Rotating black holeEntropy (arrow of time)Extremal black holeBlack braneBlack hole complementarityTheoretical physicsStatistical physicsQuantum mechanics
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Publication Info
- Year
- 1973
- Type
- article
- Volume
- 7
- Issue
- 8
- Pages
- 2333-2346
- Citations
- 6767
- Access
- Closed
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Cite This
Jacob D. Bekenstein
(1973).
Black Holes and Entropy.
Physical review. D. Particles, fields, gravitation, and cosmology/Physical review. D. Particles and fields
, 7
(8)
, 2333-2346.
https://doi.org/10.1103/physrevd.7.2333
Identifiers
- DOI
- 10.1103/physrevd.7.2333