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Charge scaling and universality in critical collapse

Charge scaling and universality in critical collapse
Charge scaling and universality in critical collapse
Consider any one-parameter family of initial data such that data with a parameter value p>p* form black holes, and data with p<p* do not. As p?p* from above ("critical collapse"), the black hole mass scales as M?(p-p*)?, where the critical exponent ? is the same for all such families of initial data. So far critical collapse has been investigated only for initial data with zero charge and zero angular momentum. Here, we allow for U(1) charge. In scalar electrodynamics coupled to gravity, with action R+|(?+iqA)?|2+F2, we consider initial data with spherical symmetry and a nonvanishing charge. From dimensional analysis and a previous calculation of Lyapunov exponents, we predict that in critical collapse the black hole mass scales as M?(p-p*)?, and the black hole charge as Q?(p-p*)?, with ?=0.374±0.001 (as for the real scalar field) and ?=0.883±0.007. We conjecture that, where there is no mass gap, this behavior generalizes to other charged matter models, with ?>~2?. We suggest the existence of universality classes with respect to parameters such as q.
1550-7998
7353-7360
Gundlach, C.
586f1eb5-3185-4b2b-8656-c29c436040fc
Martin-Garcia, J.M.
b1b0cb80-81b2-43c3-a27c-932aa2a5cbcc
Gundlach, C.
586f1eb5-3185-4b2b-8656-c29c436040fc
Martin-Garcia, J.M.
b1b0cb80-81b2-43c3-a27c-932aa2a5cbcc

Gundlach, C. and Martin-Garcia, J.M. (1996) Charge scaling and universality in critical collapse. Physical Review D, 54 (12), 7353-7360. (doi:10.1103/PhysRevD.54.7353).

Record type: Article

Abstract

Consider any one-parameter family of initial data such that data with a parameter value p>p* form black holes, and data with p<p* do not. As p?p* from above ("critical collapse"), the black hole mass scales as M?(p-p*)?, where the critical exponent ? is the same for all such families of initial data. So far critical collapse has been investigated only for initial data with zero charge and zero angular momentum. Here, we allow for U(1) charge. In scalar electrodynamics coupled to gravity, with action R+|(?+iqA)?|2+F2, we consider initial data with spherical symmetry and a nonvanishing charge. From dimensional analysis and a previous calculation of Lyapunov exponents, we predict that in critical collapse the black hole mass scales as M?(p-p*)?, and the black hole charge as Q?(p-p*)?, with ?=0.374±0.001 (as for the real scalar field) and ?=0.883±0.007. We conjecture that, where there is no mass gap, this behavior generalizes to other charged matter models, with ?>~2?. We suggest the existence of universality classes with respect to parameters such as q.

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Published date: 1996
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Local EPrints ID: 29171
URI: http://eprints.soton.ac.uk/id/eprint/29171
DOI: doi:10.1103/PhysRevD.54.7353
ISSN: 1550-7998
PURE UUID: c95da6a1-6270-450c-af60-dbffcbd55e59
ORCID for C. Gundlach: ORCID iD orcid.org/0000-0001-9585-5375

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Date deposited: 03 Jan 2007
Last modified: 16 Mar 2024 03:15

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Author: C. Gundlach ORCID iD
Author: J.M. Martin-Garcia

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