Journal Article

Multiband light curves of tidal disruption events

Giuseppe Lodato and Elena M. Rossi

in Monthly Notices of the Royal Astronomical Society

Published on behalf of The Royal Astronomical Society

Volume 410, issue 1, pages 359-367
Published in print January 2011 | ISSN: 0035-8711
Published online December 2010 | e-ISSN: 1365-2966 | DOI:
Multiband light curves of tidal disruption events

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Unambiguous detection of the tidal disruption of a star would allow an assessment of the presence and masses of supermassive black holes in quiescent galaxies. It would also provide invaluable information on bulge-scale stellar processes (such as two-body relaxation) via the rate at which stars are injected into the tidal sphere of influence of the black holes. This rate, in turn, is essential to predict gravitational radiation emission by compact object inspirals. The signature of a tidal disruption event is thought to be a fallback rate for the stellar debris on to the black hole that decreases as t−5/3. This mass flux is often assumed to yield a luminous signal that decreases in time at the same rate. In this paper, we calculate the monochromatic light curves arising from such an accretion event. Differently from previous studies, we adopt a more realistic description of the fallback rate and of the super-Eddington accretion physics. We also provide simultaneous light curves in optical, ultraviolet (UV) and X-rays. We show that, after a few months, optical and UV light curves scale as t−5/12, and are thus substantially flatter than the t−5/3 behaviour, which is a prerogative of the bolometric light curve, only. At earlier times and for black hole masses <107 M, the wind emission dominates: after reaching a peak of 1041–1043 erg s−1 at roughly a month, the light curve decreases steeply as ∼t−2.6, until the disc contribution takes over. The X-ray band, instead, is the best place to detect the t−5/3‘smoking gun’ behaviour, although it is displayed only for roughly a year, before the emission steepens exponentially.

Keywords: black hole physics; hydrodynamics; galaxies: nuclei

Journal Article.  6244 words.  Illustrated.

Subjects: Astronomy and Astrophysics

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