A Correspondence Principle for Black Holes and Strings

A. Sen; A. Sen; A. Strominger; A. Tseytlin; C. G. Callan, Jr.; E. Halyo; F. Larsen; G. Horowitz; G. Horowitz; G. T. Horowitz; G. T. Horowitz; Gary T. Horowitz; H. Lu; H. Lu; I. Klebanov; I. Klebanov; J. Horne; J. Maldacena; J. Polchinski; Joseph Polchinski; M. Cvetic; R. Gregory; R. Myers; S. Das; S. Gubser

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A Correspondence Principle for Black Holes and Strings

Authors: A. Sen
A. Sen
A. Strominger
A. Tseytlin
Jr. C. G. Callan
E. Halyo
F. Larsen
G. Horowitz
G. Horowitz
G. T. Horowitz
G. T. Horowitz
Gary T. Horowitz
H. Lu
H. Lu
I. Klebanov
I. Klebanov
J. Horne
J. Maldacena
J. Polchinski
Joseph Polchinski
M. Cvetic
R. Gregory
R. Myers
S. Das
S. Gubser
Publication date: 12 December 1996
Publisher: 'American Physical Society (APS)'
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Abstract

For most black holes in string theory, the Schwarzschild radius in string units decreases as the string coupling is reduced. We formulate a correspondence principle, which states that (i) when the size of the horizon drops below the size of a string, the typical black hole state becomes a typical state of strings and D-branes with the same charges, and (ii) the mass does not change abruptly during the transition. This provides a statistical interpretation of black hole entropy. This approach does not yield the numerical coefficient, but gives the correct dependence on mass and charge in a wide range of cases, including neutral black holes.Comment: 24 pages, one typo correcte

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