The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

Probing the roles of orientation and multiscale gas distributions in shaping the obscuration of active galactic nuclei through cosmic time

Probing the roles of orientation and multiscale gas distributions in shaping the obscuration of active galactic nuclei through cosmic time
Probing the roles of orientation and multiscale gas distributions in shaping the obscuration of active galactic nuclei through cosmic time
The origin of obscuration in active galactic nuclei (AGNs) is still an open debate. In particular, it is unclear what drives the relative contributions to the line-of-sight column densities from galaxy-scale and torus-linked obscuration. The latter source is expected to play a significant role in Unification Models, while the former is thought to be relevant in both Unification and Evolutionary models. In this work, we make use of a combination of cosmological semi-analytic models and semi-empirical prescriptions for the properties of galaxies and AGN, to study AGN obscuration. We consider a detailed object-by-object modelling of AGN evolution, including different AGN light curves (LCs), gas density profiles, and also AGN feedback-induced gas cavities. Irrespective of our assumptions on specific AGN LC or galaxy gas fractions, we find that, on the strict assumption of an exponential profile for the gas component, galaxy-scale obscuration alone can hardly reproduce the fraction of log (NH/cm-2) ≥ 24 sources at least at z ≲ 3. This requires an additional torus component with a thickness that decreases with luminosity to match the data. The torus should be present in all evolutionary stages of a visible AGN to be effective, although galaxy-scale gas obscuration may be sufficient to reproduce the obscured fraction with 22 < log (NH/cm-2) < 24 (Compton-thin, CTN) if we assume extremely compact gas disc components. The claimed drop of CTN fractions with increasing luminosity does not appear to be a consequence of AGN feedback, but rather of gas reservoirs becoming more compact with decreasing stellar mass.
1365-2966
10878–10896
Alonso-Tetilla, Alba V.
672c0f44-412a-4f1e-a98f-22463585e6ad
Shankar, Francesco
b10c91e4-85cd-4394-a18a-d4f049fd9cdb
Fontanot, Fabio
5bea4477-c8fe-4dc6-b0b6-53a8497e58c2
Menci, Nicola
e68473f0-6f7f-48b8-8b76-088d8752df6a
Valentini, Milena
c7d233e5-f075-44ba-ac45-cff3f125b4aa
Buchner, Johannes
e40a3ffc-11c5-44e0-9486-9241cea03f0d
Laloux, Brivael
a8be06b5-4182-4045-b14c-193c33134a9a
Lapi, Andrea
f696d82a-d82b-451d-9285-e51df4a1b4db
Puglisi, Annagrazia
97237841-1e6d-48fb-9133-671b6f3af18b
Alexander, David M.
49c9b059-8447-4859-8242-fa6bb8f267c7
Allevato, Viola
e74ca535-ee08-485b-a961-09c8376668c2
Andonie, Carolina
9af94180-efac-40de-8036-720cdb3838f2
Bonoli, Silvia
3b8caa29-7d4b-47a9-8dba-ec67ffcae47a
Hirschmann, Michaela
a3004aff-e242-49d0-890c-aff36446c037
López, Iván E.
b1faa3a5-76ff-4bd0-bbbe-d30d3d4aa1fc
Raimundo, Sandra I.
881da27d-b495-4512-8413-d1f512f1d208
Ramos Almeida, Cristina
ef22ad05-b6ed-433c-a5f1-390c44a2c52e
Alonso-Tetilla, Alba V.
672c0f44-412a-4f1e-a98f-22463585e6ad
Shankar, Francesco
b10c91e4-85cd-4394-a18a-d4f049fd9cdb
Fontanot, Fabio
5bea4477-c8fe-4dc6-b0b6-53a8497e58c2
Menci, Nicola
e68473f0-6f7f-48b8-8b76-088d8752df6a
Valentini, Milena
c7d233e5-f075-44ba-ac45-cff3f125b4aa
Buchner, Johannes
e40a3ffc-11c5-44e0-9486-9241cea03f0d
Laloux, Brivael
a8be06b5-4182-4045-b14c-193c33134a9a
Lapi, Andrea
f696d82a-d82b-451d-9285-e51df4a1b4db
Puglisi, Annagrazia
97237841-1e6d-48fb-9133-671b6f3af18b
Alexander, David M.
49c9b059-8447-4859-8242-fa6bb8f267c7
Allevato, Viola
e74ca535-ee08-485b-a961-09c8376668c2
Andonie, Carolina
9af94180-efac-40de-8036-720cdb3838f2
Bonoli, Silvia
3b8caa29-7d4b-47a9-8dba-ec67ffcae47a
Hirschmann, Michaela
a3004aff-e242-49d0-890c-aff36446c037
López, Iván E.
b1faa3a5-76ff-4bd0-bbbe-d30d3d4aa1fc
Raimundo, Sandra I.
881da27d-b495-4512-8413-d1f512f1d208
Ramos Almeida, Cristina
ef22ad05-b6ed-433c-a5f1-390c44a2c52e

Alonso-Tetilla, Alba V., Shankar, Francesco, Fontanot, Fabio, Menci, Nicola, Valentini, Milena, Buchner, Johannes, Laloux, Brivael, Lapi, Andrea, Puglisi, Annagrazia, Alexander, David M., Allevato, Viola, Andonie, Carolina, Bonoli, Silvia, Hirschmann, Michaela, López, Iván E., Raimundo, Sandra I. and Ramos Almeida, Cristina (2024) Probing the roles of orientation and multiscale gas distributions in shaping the obscuration of active galactic nuclei through cosmic time. Monthly Notices Of The Royal Astronomical Society, 527 (4), 10878–10896. (doi:10.1093/mnras/stad3265).

Record type: Article

Abstract

The origin of obscuration in active galactic nuclei (AGNs) is still an open debate. In particular, it is unclear what drives the relative contributions to the line-of-sight column densities from galaxy-scale and torus-linked obscuration. The latter source is expected to play a significant role in Unification Models, while the former is thought to be relevant in both Unification and Evolutionary models. In this work, we make use of a combination of cosmological semi-analytic models and semi-empirical prescriptions for the properties of galaxies and AGN, to study AGN obscuration. We consider a detailed object-by-object modelling of AGN evolution, including different AGN light curves (LCs), gas density profiles, and also AGN feedback-induced gas cavities. Irrespective of our assumptions on specific AGN LC or galaxy gas fractions, we find that, on the strict assumption of an exponential profile for the gas component, galaxy-scale obscuration alone can hardly reproduce the fraction of log (NH/cm-2) ≥ 24 sources at least at z ≲ 3. This requires an additional torus component with a thickness that decreases with luminosity to match the data. The torus should be present in all evolutionary stages of a visible AGN to be effective, although galaxy-scale gas obscuration may be sufficient to reproduce the obscured fraction with 22 < log (NH/cm-2) < 24 (Compton-thin, CTN) if we assume extremely compact gas disc components. The claimed drop of CTN fractions with increasing luminosity does not appear to be a consequence of AGN feedback, but rather of gas reservoirs becoming more compact with decreasing stellar mass.

Text
stad3265 - Version of Record
Available under License Creative Commons Attribution.
Download (3MB)

More information

Accepted/In Press date: 20 October 2023
e-pub ahead of print date: 25 October 2023
Published date: 4 January 2024
Learn more about Institute for Life Sciences research

Identifiers

Local EPrints ID: 489249
URI: http://eprints.soton.ac.uk/id/eprint/489249
DOI: doi:10.1093/mnras/stad3265
ISSN: 1365-2966
PURE UUID: a82c1491-0e8a-4eec-b1d4-36d5e845c41a

Catalogue record

Date deposited: 18 Apr 2024 16:45
Last modified: 23 Apr 2024 18:00

Export record

Altmetrics

Contributors

Author: Alba V. Alonso-Tetilla
Author: Francesco Shankar
Author: Fabio Fontanot
Author: Nicola Menci
Author: Milena Valentini
Author: Johannes Buchner
Author: Brivael Laloux
Author: Andrea Lapi
Author: Annagrazia Puglisi
Author: David M. Alexander
Author: Viola Allevato
Author: Carolina Andonie
Author: Silvia Bonoli
Author: Michaela Hirschmann
Author: Iván E. López
Author: Sandra I. Raimundo
Author: Cristina Ramos Almeida

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×