Reverberation mapping (or Echo mapping) is an
astrophysical technique for measuring the structure of the
broad-line region (BLR) around a
supermassive black hole at the center of an
active galaxy, and thus estimating the hole's mass. It is considered a "primary" mass estimation technique, i.e., the mass is measured directly from the motion that its
gravitational force induces in the nearby gas.
defines a direct relation between the mass of a central object and the speed of a smaller object in orbit around the central mass. Thus, for matter orbiting a black hole, the black-hole mass
is related by the formula
:
to the
RMS velocity Δ''V'' of gas moving near the black hole in the broad emission-line region, measured from the
Doppler broadening of the gaseous emission lines. In this formula, ''R''
BLR is the radius of the broad-line region; ''G'' is the
constant of gravitation; and ''f'' is a poorly known "form factor" that depends on the shape of the BLR.
While Δ''V'' can be measured directly using
spectroscopy
Spectroscopy is the field of study that measures and interprets electromagnetic spectra. In narrower contexts, spectroscopy is the precise study of color as generalized from visible light to all bands of the electromagnetic spectrum.
Spectro ...
, the necessary determination of ''R''
BLR is much less straightforward. This is where reverberation mapping comes into play.
[B. M. Peterson, K. Horne]
Reverberation Mapping of Active Galactic Nuclei
(2004). It utilizes the fact that the emission-line fluxes vary strongly in response to changes in the continuum, i.e., the light from the
accretion disk near the black hole. Put simply, if the brightness of the accretion disk varies, the emission lines, which are excited in response to the accretion disk's light, will "reverberate", that is, vary in response. But it will take some time for light from the accretion disk to reach the broad-line region. Thus, the emission-line response is delayed with respect to changes in the continuum. Assuming that this delay is solely due to light travel times, the distance traveled by the light, corresponding to the radius of the broad emission-line region, can be measured.
Less than 40
active galactic nuclei have been accurately mapped in this way. An alternative approach is to use an empirical
correlation between ''R''
BLR and the continuum luminosity.
[
Another uncertainty is the value of ''f''. In principle, the response of the BLR to variations in the continuum could be used to map out the three-dimensional structure of the BLR. In practice, the amount and quality of data required to carry out such a deconvolution is prohibitive. Until about 2004, ''f'' was estimated ab initio based on simple models for the structure of the BLR. More recently, the value of ''f'' has been determined so as to bring the M–sigma relation for active galaxies into the best possible agreement with the M–sigma relation for quiescent galaxies.][ When ''f'' is determined in this way, reverberation mapping becomes a "secondary", rather than "primary", mass estimation technique.
]
References and notes
{{Reflist
External links
Reverberation Mapping
ppt-presentation (2005)
Active galaxies
Astronomical imaging
Concepts in astrophysics
Observational astronomy
Supermassive black holes
Signal processing