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The properties of the interstellar medium in dusty, star-forming galaxies at z∼2−4: the shape of the CO spectral line energy distributions

The properties of the interstellar medium in dusty, star-forming galaxies at z∼2−4: the shape of the CO spectral line energy distributions
The properties of the interstellar medium in dusty, star-forming galaxies at z∼2−4: the shape of the CO spectral line energy distributions
The molecular gas in the interstellar medium (ISM) of star-forming galaxy populations exhibits diverse physical properties. We investigate the 12CO excitation of twelve dusty, luminous star-forming galaxies at z∼2−4 by combining observations of the 12CO from Jup=1 to Jup=8. The spectral line energy distribution (SLED) has a similar shape to NGC 253, M82, and local ULIRGs, with much stronger excitation than the Milky Way inner disc. By combining with resolved dust continuum sizes from high-resolution 870-μm ALMA observations and dust mass measurements determined from multi-wavelength SED fitting, we measure the relationship between the 12CO SLED and probable physical drivers of excitation: star-formation efficiency, the average intensity of the radiation field ⟨U⟩, and the star-formation rate surface density. The primary driver of high-Jup 12CO excitation in star-forming galaxies is star-formation rate surface density. We use the ratio of the CO(3−2) and CO(6−5) line fluxes to infer the CO excitation in each source and find that the average ratios for our sample are elevated compared to observations of low-redshift, less actively star-forming galaxies and agree well with predictions from numerical models that relate the ISM excitation to the star-formation rate surface density. The significant scatter in the line ratios of a factor ≈3 within our sample likely reflects intrinsic variations in the ISM properties which may be caused by other effects on the excitation of the molecular gas, such as cosmic ray ionization rates and mechanical heating through turbulence dissipation.
astro-ph.GA, astro-ph.CO
1365-2966
1149-1165
Taylor, Dominic J.
abd05967-47ab-4972-afc7-2e85d6d3fb46
Swinbank, A.M.
53256483-8faf-4843-81fd-c494cb3369fb
Smail, Ian
bde55422-5add-46d9-a750-ec89f7015638
Puglisi, Annagrazia
97237841-1e6d-48fb-9133-671b6f3af18b
Birkin, Jack E.
654528cc-a268-4234-8c49-554ddf4d3697
Dudzeviciute, Ugne
e13a8754-3933-4f8b-a89c-f775517397a0
Chen, Chian-Chou
bf62035f-f6f4-452c-9273-ed3e81bbdb30
Ikarashi, S.
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Castillo, Marta Frias
cb790f8d-5bcc-44bd-8422-293fb5f4116e
Weiss, Axel
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Li, Zefeng
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Chapman, Scott C.
a594532c-ac04-4699-baf8-7eb61711152c
Jansen, Jasper
2124c706-f0b8-4fa2-bf8e-06e264cf7bc5
Jimenez-Andrade, E.F.
cba047a8-83a6-44ca-82fa-da0e04ff21e3
Morabito, Leah K.
ba511a9e-71f5-40ea-991a-a205bb125e03
Murphy, Eric J.
ffaa826e-bbdf-4526-8143-5db5316f5d86
Rybak, Matus
56631588-e935-429b-9fae-fb589c49683c
Werf, P.P. van der
d68ca67e-e29d-48b4-b1cc-a3d4fcef1cf8
Taylor, Dominic J.
abd05967-47ab-4972-afc7-2e85d6d3fb46
Swinbank, A.M.
53256483-8faf-4843-81fd-c494cb3369fb
Smail, Ian
bde55422-5add-46d9-a750-ec89f7015638
Puglisi, Annagrazia
97237841-1e6d-48fb-9133-671b6f3af18b
Birkin, Jack E.
654528cc-a268-4234-8c49-554ddf4d3697
Dudzeviciute, Ugne
e13a8754-3933-4f8b-a89c-f775517397a0
Chen, Chian-Chou
bf62035f-f6f4-452c-9273-ed3e81bbdb30
Ikarashi, S.
0ffd8b41-1204-448c-bfdf-3bf1ccbbcf6a
Castillo, Marta Frias
cb790f8d-5bcc-44bd-8422-293fb5f4116e
Weiss, Axel
911844d4-61b7-4ace-83d9-278685f5ffb6
Li, Zefeng
7ff95a64-bf1c-4637-9908-4184eabfb006
Chapman, Scott C.
a594532c-ac04-4699-baf8-7eb61711152c
Jansen, Jasper
2124c706-f0b8-4fa2-bf8e-06e264cf7bc5
Jimenez-Andrade, E.F.
cba047a8-83a6-44ca-82fa-da0e04ff21e3
Morabito, Leah K.
ba511a9e-71f5-40ea-991a-a205bb125e03
Murphy, Eric J.
ffaa826e-bbdf-4526-8143-5db5316f5d86
Rybak, Matus
56631588-e935-429b-9fae-fb589c49683c
Werf, P.P. van der
d68ca67e-e29d-48b4-b1cc-a3d4fcef1cf8

Taylor, Dominic J., Swinbank, A.M., Smail, Ian, Puglisi, Annagrazia, Birkin, Jack E., Dudzeviciute, Ugne, Chen, Chian-Chou, Ikarashi, S., Castillo, Marta Frias, Weiss, Axel, Li, Zefeng, Chapman, Scott C., Jansen, Jasper, Jimenez-Andrade, E.F., Morabito, Leah K., Murphy, Eric J., Rybak, Matus and Werf, P.P. van der (2024) The properties of the interstellar medium in dusty, star-forming galaxies at z∼2−4: the shape of the CO spectral line energy distributions. Monthly Notices of the Royal Astronomical Society, 536, 1149-1165. (doi:10.48550/arXiv.2411.14271).

Record type: Article

Abstract

The molecular gas in the interstellar medium (ISM) of star-forming galaxy populations exhibits diverse physical properties. We investigate the 12CO excitation of twelve dusty, luminous star-forming galaxies at z∼2−4 by combining observations of the 12CO from Jup=1 to Jup=8. The spectral line energy distribution (SLED) has a similar shape to NGC 253, M82, and local ULIRGs, with much stronger excitation than the Milky Way inner disc. By combining with resolved dust continuum sizes from high-resolution 870-μm ALMA observations and dust mass measurements determined from multi-wavelength SED fitting, we measure the relationship between the 12CO SLED and probable physical drivers of excitation: star-formation efficiency, the average intensity of the radiation field ⟨U⟩, and the star-formation rate surface density. The primary driver of high-Jup 12CO excitation in star-forming galaxies is star-formation rate surface density. We use the ratio of the CO(3−2) and CO(6−5) line fluxes to infer the CO excitation in each source and find that the average ratios for our sample are elevated compared to observations of low-redshift, less actively star-forming galaxies and agree well with predictions from numerical models that relate the ISM excitation to the star-formation rate surface density. The significant scatter in the line ratios of a factor ≈3 within our sample likely reflects intrinsic variations in the ISM properties which may be caused by other effects on the excitation of the molecular gas, such as cosmic ray ionization rates and mechanical heating through turbulence dissipation.

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More information

Accepted/In Press date: 20 November 2024
e-pub ahead of print date: 26 November 2024
Published date: 12 December 2024
Keywords: astro-ph.GA, astro-ph.CO

Identifiers

Local EPrints ID: 509269
URI: http://eprints.soton.ac.uk/id/eprint/509269
DOI: doi:10.48550/arXiv.2411.14271
ISSN: 1365-2966
PURE UUID: 1823ac2b-f40a-43d0-8087-43c3b0d0c4a3

Catalogue record

Date deposited: 17 Feb 2026 17:40
Last modified: 17 Feb 2026 17:41

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Contributors

Author: Dominic J. Taylor
Author: A.M. Swinbank
Author: Ian Smail
Author: Annagrazia Puglisi
Author: Jack E. Birkin
Author: Ugne Dudzeviciute
Author: Chian-Chou Chen
Author: S. Ikarashi
Author: Marta Frias Castillo
Author: Axel Weiss
Author: Zefeng Li
Author: Scott C. Chapman
Author: Jasper Jansen
Author: E.F. Jimenez-Andrade
Author: Leah K. Morabito
Author: Eric J. Murphy
Author: Matus Rybak
Author: P.P. van der Werf

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