On Estimating the Mass of Keplerian Accretion Disks in H2O Maser Galaxies

H2O maser disks with Keplerian rotation in active galactic nuclei offer a clean way to determine accurate black hole mass and the Hubble constant. An important assumption made in using a Keplerian H2O maser disk for measuring black hole mass and the Hubble constant is that the disk mass is negligibl...

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Published inThe Astrophysical journal Vol. 859; no. 2
Main Authors Kuo, C. Y., Reid, M. J., Braatz, J. A., Gao, F., Impellizzeri, C. M. V., Chien, W. T.
Format Journal Article
LanguageEnglish
Published Philadelphia The American Astronomical Society 01.06.2018
IOP Publishing
Subjects
Accretion
Accretion disks
accretion, accretion disks
Active galactic nuclei
Astrophysics
Black holes
Galactic rotation
Galaxies
galaxies: active
galaxies: ISM
galaxies: nuclei
Gravitation
Gravitational effects
Hubble constant
masers
Rotating disks
Stars & galaxies
Systematic errors
Three dimensional models
Velocity
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Summary:H2O maser disks with Keplerian rotation in active galactic nuclei offer a clean way to determine accurate black hole mass and the Hubble constant. An important assumption made in using a Keplerian H2O maser disk for measuring black hole mass and the Hubble constant is that the disk mass is negligible compared to the black hole mass. A simple and useful model of Huré et al. can be used to test this assumption. In that work, the authors apply a linear disk model to a position-dynamical mass diagram and re-analyze position-velocity data from H2O maser disks associated with active galactic nuclei. They claim that a maser disk with nearly perfect Keplerian rotation could have a disk mass comparable to the black hole mass. This would imply that ignoring the effects of disk self-gravity can lead to large systematic errors in the measurement of black hole mass and the Hubble constant. We examine their methods and find that their large estimated disk masses of Keplerian disks are likely the result of their use of projected instead of three-dimensional position and velocity information. To place better constraints on the disk masses of Keplerian maser systems, we incorporate disk self-gravity into a three-dimensional Bayesian modeling program for maser disks and also evaluate constraints based on the physical conditions for disks that support water maser emission. We find that there is little evidence that disk masses are dynamically important at the 1% level compared to the black holes.
Bibliography:Galaxies and Cosmology
AAS08843
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aabff1