Abstract
There are firm indications that Sgr A*, a compact, nonthermal radio source at the Galactic center, may be powered by the dissipation of gravitational energy as gas trapped from an ambient wind descends down the potential well, first through a quasi-spherical inflow (extending out to ∼3 × 1016 cm) and then through a small accretion disk at ≲5-10 Schwarzschild radii. Earlier three-dimensional Bondi-Hoyle numerical simulations have indicated that fluctuations in the accreted specific angular momentum can lead to a variability in the disk flux on a timescale of years. With greatly improved flux measurements at K and H, and the hint of a ∼10 minute modulation in the IR luminosity, it is crucial to model the disk emission much more precisely than has been attempted thus far. In this Letter we take into account the effects of Doppler and gravitational redshifts, the light-travel time factor, and the light bending near the black hole to determine the measurable spectrum of Sgr A* in the increasingly important 1013 Hz ≲ v ≲ 1016 Hz frequency range. We find that the relativistic disk spectrum is much softer than its Newtonian counterpart, with a predicted UV flux roughly an order of magnitude smaller than had previously been anticipated. In addition, we find that when the physical conditions in the disk are taken to be consistent with the properties of the quasi-spherical infall (specifically, in terms of the accretion rate and disk size), only a slowly spinning or Schwarzschild black hole appears to fit the observations. Our calculations also reveal that the disk flux is much more weakly dependent on the observer's inclination angle than had been suspected on the basis of earlier Newtonian estimates.
Original language | English (US) |
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Pages (from-to) | L17-L20 |
Journal | Astrophysical Journal |
Volume | 443 |
Issue number | 1 PART 2 |
DOIs | |
State | Published - Apr 10 1995 |
Keywords
- Accretion, accretion disks
- Black hole physics
- Galaxy: center
- Relativity
ASJC Scopus subject areas
- Astronomy and Astrophysics
- Space and Planetary Science