Collisional Dark Matter and the Origin of Massive Black Holes

D. Arnett; D. Lynden-Bell; D. N. Spergel; E. D. Carlson; G. Quinlan; G. Xu; H. Bondi; H. Cohen; J. F. Navarro; J. Magorrian; J. N. Bahcall; J. P. Ostriker; M. C. Begelman; M. E. Machacek; M. Rees; P. Hodge; T. A. Abel; Z. Haiman

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Collisional Dark Matter and the Origin of Massive Black Holes

Authors: D. Arnett
D. Lynden-Bell
D. N. Spergel
E. D. Carlson
G. Quinlan
G. Xu
H. Bondi
H. Cohen
J. F. Navarro
J. Magorrian
J. N. Bahcall
J. P. Ostriker
M. C. Begelman
M. E. Machacek
M. Rees
P. Hodge
T. A. Abel
Z. Haiman
Publication date: 17 April 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

If the cosmological dark matter is primarily in the form of an elementary particle which has cross section and mass for self-interaction having a ratio similar to that of ordinary nuclear matter, then seed black holes (formed in stellar collapse) will grow in a Hubble time, due to accretion of the dark matter, to a mass range 10^6 - 10^9 solar masses. Furthermore, the dependence of the final black hole mass on the galaxy velocity dispersion will be approximately as observed and the growth rate will show a time dependence consistent with observations. Other astrophysical consequences of collisional dark matter and tests of the idea are noted.Comment: 7 pages, no figures, LaTeX2e, Accepted for publication in Phys. Rev. Lett. Changed conten

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