UNIFICATION OF THE FUNDAMENTAL PLANE AND SUPER MASSIVE BLACK HOLE MASSES

ABSTRACT According to the virial theorem, all gravitational systems in equilibrium sit on a plane in the three-dimensional parameter space defined by their mass, size, and second moment of the velocity tensor. While these quantities cannot be directly observed, there are suitable proxies: the lumino...

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Published in:The Astrophysical journal 2016-11, Vol.831 (2), p.134
Main Author: Bosch, Remco C. E. van den
Format: Article
Language:English
Subjects:
Astrophysics
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
BLACK HOLES
Correlation
CORRELATIONS
Disks
DISPERSIONS
Galactic bulge
Galactic clusters
GALAXIES
galaxies: bulges
galaxies: fundamental parameters
galaxies: kinematics and dynamics
GALAXY CLUSTERS
GRAVITATION
LUMINOSITY
MASS
QUASARS
quasars: supermassive black holes
SPACE
Stars & galaxies
Supermassive black holes
Surface brightness
Tensors
VELOCITY
Virial theorem
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description ABSTRACT According to the virial theorem, all gravitational systems in equilibrium sit on a plane in the three-dimensional parameter space defined by their mass, size, and second moment of the velocity tensor. While these quantities cannot be directly observed, there are suitable proxies: the luminosity Lk, half-light radius Re, and dispersion . These proxies indeed lie on a very tight fundamental plane (FP). How do the black holes (BHs) in the centers of galaxies relate to the FP? Their masses are known to exhibit no strong correlation with total galaxy mass, but they do correlate weakly with bulge mass (when present), and extremely well with the velocity dispersion through the relation. These facts together imply that a tight plane must also exist defined by BH mass, total galaxy mass, and size. Here, I show that this is indeed the case using a heterogeneous set of 230 BHs. The sample includes BHs from zero to 10 billion solar masses and host galaxies ranging from low surface brightness dwarfs, through bulgeless disks, to brightest cluster galaxies. The resulting BH-size-luminosity relation has the same amount of scatter as the M*-σ relation and is aligned with the galaxy FP, such that it is just a reprojection of . The inferred BH-size-mass relation is . These relationships are universal and extend to galaxies without bulges. This implies that the BH is primarily correlated with its global velocity dispersion and not with the properties of the bulge. I show that the classical bulge-mass relation is a projection of the M*-σ relation. When the velocity dispersion cannot be measured (at high z or low dispersions), the BH-size-mass relation should be used as a proxy for BH mass in favor of just galaxy or bulge mass.
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These facts together imply that a tight plane must also exist defined by BH mass, total galaxy mass, and size. Here, I show that this is indeed the case using a heterogeneous set of 230 BHs. The sample includes BHs from zero to 10 billion solar masses and host galaxies ranging from low surface brightness dwarfs, through bulgeless disks, to brightest cluster galaxies. The resulting BH-size-luminosity relation has the same amount of scatter as the M*-σ relation and is aligned with the galaxy FP, such that it is just a reprojection of . The inferred BH-size-mass relation is . These relationships are universal and extend to galaxies without bulges. This implies that the BH is primarily correlated with its global velocity dispersion and not with the properties of the bulge. I show that the classical bulge-mass relation is a projection of the M*-σ relation. 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Here, I show that this is indeed the case using a heterogeneous set of 230 BHs. The sample includes BHs from zero to 10 billion solar masses and host galaxies ranging from low surface brightness dwarfs, through bulgeless disks, to brightest cluster galaxies. The resulting BH-size-luminosity relation has the same amount of scatter as the M*-σ relation and is aligned with the galaxy FP, such that it is just a reprojection of . The inferred BH-size-mass relation is . These relationships are universal and extend to galaxies without bulges. This implies that the BH is primarily correlated with its global velocity dispersion and not with the properties of the bulge. I show that the classical bulge-mass relation is a projection of the M*-σ relation. 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subjects Astrophysics
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
BLACK HOLES
Correlation
CORRELATIONS
Disks
DISPERSIONS
Galactic bulge
Galactic clusters
GALAXIES
galaxies: bulges
galaxies: fundamental parameters
galaxies: kinematics and dynamics
GALAXY CLUSTERS
GRAVITATION
LUMINOSITY
MASS
QUASARS
quasars: supermassive black holes
SPACE
Stars & galaxies
Supermassive black holes
Surface brightness
Tensors
VELOCITY
Virial theorem
title UNIFICATION OF THE FUNDAMENTAL PLANE AND SUPER MASSIVE BLACK HOLE MASSES
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