Galaxies often contain large reservoirs of molecular gas which shape their
evolution. This can be through cooling of the gas -- which leads to star
formation, or accretion onto the central supermassive black hole -- which fuels
AGN activity and produces powerful feedback. Molecular gas has been detected in
early-type galaxies on scales of just a few tens to hundreds of solar masses by
searching for absorption against their compact radio cores. Using this
technique, ALMA has found absorption in several brightest cluster galaxies,
some of which show molecular gas moving towards their galaxy's core at hundreds
of km/s. In this paper we constrain the location of this absorbing gas by
comparing each galaxy's molecular emission and absorption. In four galaxies,
the absorption properties are consistent with chance alignments between the
continuum and a fraction of the molecular clouds visible in emission. In four
others, the properties of the absorption are inconsistent with this scenario.
In these systems the absorption is likely produced by a separate population of
molecular clouds in close proximity to the galaxy core and with high inward
velocities and velocity dispersions. We thus deduce the existence of two types
of absorber, caused by chance alignments between the radio core and: (i) a
fraction of the molecular clouds visible in emission, and (ii) molecular clouds
close to the AGN, in the process of accretion. We also present the first ALMA
observations of molecular emission in S555, Abell 2390, RXC J1350.3+0940 and
RXC J1603.6+1553 -- with the latter three having molecular masses of
$>10^10$M$_ødot$.
Description
Does absorption against AGN reveal supermassive black hole accretion?
%0 Generic
%1 rose2022absorption
%A Rose, Tom
%A McNamara, B. R.
%A Combes, F.
%A Edge, A. C.
%A Fabian, A. C.
%A Gaspari, M.
%A Russell, H.
%A Salomé, P.
%A Tremblay, G.
%A Ferland, G.
%D 2022
%K library
%T Does absorption against AGN reveal supermassive black hole accretion?
%U http://arxiv.org/abs/2210.14922
%X Galaxies often contain large reservoirs of molecular gas which shape their
evolution. This can be through cooling of the gas -- which leads to star
formation, or accretion onto the central supermassive black hole -- which fuels
AGN activity and produces powerful feedback. Molecular gas has been detected in
early-type galaxies on scales of just a few tens to hundreds of solar masses by
searching for absorption against their compact radio cores. Using this
technique, ALMA has found absorption in several brightest cluster galaxies,
some of which show molecular gas moving towards their galaxy's core at hundreds
of km/s. In this paper we constrain the location of this absorbing gas by
comparing each galaxy's molecular emission and absorption. In four galaxies,
the absorption properties are consistent with chance alignments between the
continuum and a fraction of the molecular clouds visible in emission. In four
others, the properties of the absorption are inconsistent with this scenario.
In these systems the absorption is likely produced by a separate population of
molecular clouds in close proximity to the galaxy core and with high inward
velocities and velocity dispersions. We thus deduce the existence of two types
of absorber, caused by chance alignments between the radio core and: (i) a
fraction of the molecular clouds visible in emission, and (ii) molecular clouds
close to the AGN, in the process of accretion. We also present the first ALMA
observations of molecular emission in S555, Abell 2390, RXC J1350.3+0940 and
RXC J1603.6+1553 -- with the latter three having molecular masses of
$>10^10$M$_ødot$.
@misc{rose2022absorption,
abstract = {Galaxies often contain large reservoirs of molecular gas which shape their
evolution. This can be through cooling of the gas -- which leads to star
formation, or accretion onto the central supermassive black hole -- which fuels
AGN activity and produces powerful feedback. Molecular gas has been detected in
early-type galaxies on scales of just a few tens to hundreds of solar masses by
searching for absorption against their compact radio cores. Using this
technique, ALMA has found absorption in several brightest cluster galaxies,
some of which show molecular gas moving towards their galaxy's core at hundreds
of km/s. In this paper we constrain the location of this absorbing gas by
comparing each galaxy's molecular emission and absorption. In four galaxies,
the absorption properties are consistent with chance alignments between the
continuum and a fraction of the molecular clouds visible in emission. In four
others, the properties of the absorption are inconsistent with this scenario.
In these systems the absorption is likely produced by a separate population of
molecular clouds in close proximity to the galaxy core and with high inward
velocities and velocity dispersions. We thus deduce the existence of two types
of absorber, caused by chance alignments between the radio core and: (i) a
fraction of the molecular clouds visible in emission, and (ii) molecular clouds
close to the AGN, in the process of accretion. We also present the first ALMA
observations of molecular emission in S555, Abell 2390, RXC J1350.3+0940 and
RXC J1603.6+1553 -- with the latter three having molecular masses of
$>10^{10}$M$_{\odot}$.},
added-at = {2022-10-28T14:17:01.000+0200},
author = {Rose, Tom and McNamara, B. R. and Combes, F. and Edge, A. C. and Fabian, A. C. and Gaspari, M. and Russell, H. and Salomé, P. and Tremblay, G. and Ferland, G.},
biburl = {https://www.bibsonomy.org/bibtex/299b9d7fa038095d38a3e8280e408eb79/gpkulkarni},
description = {Does absorption against AGN reveal supermassive black hole accretion?},
interhash = {ded73020d23ce5f81c231740eb832133},
intrahash = {99b9d7fa038095d38a3e8280e408eb79},
keywords = {library},
note = {cite arxiv:2210.14922Comment: Submitted to MNRAS},
timestamp = {2022-10-28T14:17:01.000+0200},
title = {Does absorption against AGN reveal supermassive black hole accretion?},
url = {http://arxiv.org/abs/2210.14922},
year = 2022
}