Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies

Research output: Contribution to journalJournal articleResearchpeer-review

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Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies. / Ramburuth-Hurt, T.; De Cia, A.; Krogager, J. -K.; Ledoux, C.; Petitjean, P.; Peroux, C.; Dessauges-Zavadsky, M.; Fynbo, J.; Wendt, M.; Bouche, N. F.; Konstantopoulou, C.; Jermann, I.

In: Astronomy & Astrophysics, Vol. 672, A68, 29.03.2023.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Ramburuth-Hurt, T, De Cia, A, Krogager, J-K, Ledoux, C, Petitjean, P, Peroux, C, Dessauges-Zavadsky, M, Fynbo, J, Wendt, M, Bouche, NF, Konstantopoulou, C & Jermann, I 2023, 'Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies', Astronomy & Astrophysics, vol. 672, A68. https://doi.org/10.1051/0004-6361/202244609

APA

Ramburuth-Hurt, T., De Cia, A., Krogager, J. -K., Ledoux, C., Petitjean, P., Peroux, C., Dessauges-Zavadsky, M., Fynbo, J., Wendt, M., Bouche, N. F., Konstantopoulou, C., & Jermann, I. (2023). Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies. Astronomy & Astrophysics, 672, [A68]. https://doi.org/10.1051/0004-6361/202244609

Vancouver

Ramburuth-Hurt T, De Cia A, Krogager J-K, Ledoux C, Petitjean P, Peroux C et al. Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies. Astronomy & Astrophysics. 2023 Mar 29;672. A68. https://doi.org/10.1051/0004-6361/202244609

Author

Ramburuth-Hurt, T. ; De Cia, A. ; Krogager, J. -K. ; Ledoux, C. ; Petitjean, P. ; Peroux, C. ; Dessauges-Zavadsky, M. ; Fynbo, J. ; Wendt, M. ; Bouche, N. F. ; Konstantopoulou, C. ; Jermann, I. / Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies. In: Astronomy & Astrophysics. 2023 ; Vol. 672.

Bibtex

@article{5ead3c59ad4b43b8ae02ca5b6da2b4b0,
title = "Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies",
abstract = "The chemical composition of gas in galaxies can be measured in great detail using absorption spectroscopy. By studying gas in galaxies in this way, it is possible to investigate small and faint galaxies, which are the most numerous in the universe. In particular, the chemical distribution of gas in absorbing systems gives us insight into cycles of gas in and around galaxies. In this work we study chemical enrichment within 64 damped Lyman-ff absorption systems (DLAs) for redshifts in the range 1:7 < z < 4:2. We use high-resolution spectra from VLT /UVES to infer dust depletion from relative abundances of several metals. Specifically, we performed a componentby-component analysis within DLAs, and characterised variations in their chemical enrichment. Unlike hydrogen, the metal columns can be characterised according to their individual components. We used them to derive the dust depletion, which is an indicator of chemical enrichment. Our main results are as follows. Firstly, we find that some DLAs are chemically diverse within themselves (with the measure of dust depletion [Zn /Fe] fit ranging up to 0.62 dex within a single system), suggesting that the absorbing gas within these galaxies is chemically diverse. Secondly, although we do not find a clear trend of decreasing dust depletion with redshift, we do see that the most chemically enriched systems are at lower redshifts. We also observe evidence for dust-poor components at all redshifts, which may be due to the accretion of pristine gas onto galaxies. By combining the chemical and kinematic properties of the individual gas components, we observe potential signatures of infalling gas with low depletion at velocities below similar to 100 km s (-1), and outflows with high depletion and velocities of similar to 600 km s(-1). Finally, we find over-abundances of alpha-elements (an enhancement of similar to 0.3 dex) and under-abundances of Mn in several gas components, which is likely a signature of core-collapse supernovae nucleosythesis in the ISM. We observe these effects mostly at lower levels of chemical enrichment.",
keywords = "galaxies: ISM, galaxies: kinematics and dynamics, dust, extinction, evolution, quasars: absorption lines, LY-ALPHA SYSTEMS, MASS-METALLICITY RELATION, DAMPED LYMAN, MOLECULAR-HYDROGEN, INTERSTELLAR ABUNDANCES, ELEMENTAL ABUNDANCES, DEPLETION PATTERN, DWARF GALAXIES, EVOLUTION, CLOUD",
author = "T. Ramburuth-Hurt and {De Cia}, A. and Krogager, {J. -K.} and C. Ledoux and P. Petitjean and C. Peroux and M. Dessauges-Zavadsky and J. Fynbo and M. Wendt and Bouche, {N. F.} and C. Konstantopoulou and I. Jermann",
year = "2023",
month = mar,
day = "29",
doi = "10.1051/0004-6361/202244609",
language = "English",
volume = "672",
journal = "Astronomy & Astrophysics",
issn = "0004-6361",
publisher = "E D P Sciences",

}

RIS

TY - JOUR

T1 - Chemical diversity of gas in distant galaxies Metal and dust enrichment and variations within absorbing galaxies

AU - Ramburuth-Hurt, T.

AU - De Cia, A.

AU - Krogager, J. -K.

AU - Ledoux, C.

AU - Petitjean, P.

AU - Peroux, C.

AU - Dessauges-Zavadsky, M.

AU - Fynbo, J.

AU - Wendt, M.

AU - Bouche, N. F.

AU - Konstantopoulou, C.

AU - Jermann, I.

PY - 2023/3/29

Y1 - 2023/3/29

N2 - The chemical composition of gas in galaxies can be measured in great detail using absorption spectroscopy. By studying gas in galaxies in this way, it is possible to investigate small and faint galaxies, which are the most numerous in the universe. In particular, the chemical distribution of gas in absorbing systems gives us insight into cycles of gas in and around galaxies. In this work we study chemical enrichment within 64 damped Lyman-ff absorption systems (DLAs) for redshifts in the range 1:7 < z < 4:2. We use high-resolution spectra from VLT /UVES to infer dust depletion from relative abundances of several metals. Specifically, we performed a componentby-component analysis within DLAs, and characterised variations in their chemical enrichment. Unlike hydrogen, the metal columns can be characterised according to their individual components. We used them to derive the dust depletion, which is an indicator of chemical enrichment. Our main results are as follows. Firstly, we find that some DLAs are chemically diverse within themselves (with the measure of dust depletion [Zn /Fe] fit ranging up to 0.62 dex within a single system), suggesting that the absorbing gas within these galaxies is chemically diverse. Secondly, although we do not find a clear trend of decreasing dust depletion with redshift, we do see that the most chemically enriched systems are at lower redshifts. We also observe evidence for dust-poor components at all redshifts, which may be due to the accretion of pristine gas onto galaxies. By combining the chemical and kinematic properties of the individual gas components, we observe potential signatures of infalling gas with low depletion at velocities below similar to 100 km s (-1), and outflows with high depletion and velocities of similar to 600 km s(-1). Finally, we find over-abundances of alpha-elements (an enhancement of similar to 0.3 dex) and under-abundances of Mn in several gas components, which is likely a signature of core-collapse supernovae nucleosythesis in the ISM. We observe these effects mostly at lower levels of chemical enrichment.

AB - The chemical composition of gas in galaxies can be measured in great detail using absorption spectroscopy. By studying gas in galaxies in this way, it is possible to investigate small and faint galaxies, which are the most numerous in the universe. In particular, the chemical distribution of gas in absorbing systems gives us insight into cycles of gas in and around galaxies. In this work we study chemical enrichment within 64 damped Lyman-ff absorption systems (DLAs) for redshifts in the range 1:7 < z < 4:2. We use high-resolution spectra from VLT /UVES to infer dust depletion from relative abundances of several metals. Specifically, we performed a componentby-component analysis within DLAs, and characterised variations in their chemical enrichment. Unlike hydrogen, the metal columns can be characterised according to their individual components. We used them to derive the dust depletion, which is an indicator of chemical enrichment. Our main results are as follows. Firstly, we find that some DLAs are chemically diverse within themselves (with the measure of dust depletion [Zn /Fe] fit ranging up to 0.62 dex within a single system), suggesting that the absorbing gas within these galaxies is chemically diverse. Secondly, although we do not find a clear trend of decreasing dust depletion with redshift, we do see that the most chemically enriched systems are at lower redshifts. We also observe evidence for dust-poor components at all redshifts, which may be due to the accretion of pristine gas onto galaxies. By combining the chemical and kinematic properties of the individual gas components, we observe potential signatures of infalling gas with low depletion at velocities below similar to 100 km s (-1), and outflows with high depletion and velocities of similar to 600 km s(-1). Finally, we find over-abundances of alpha-elements (an enhancement of similar to 0.3 dex) and under-abundances of Mn in several gas components, which is likely a signature of core-collapse supernovae nucleosythesis in the ISM. We observe these effects mostly at lower levels of chemical enrichment.

KW - galaxies: ISM

KW - galaxies: kinematics and dynamics

KW - dust, extinction

KW - evolution

KW - quasars: absorption lines

KW - LY-ALPHA SYSTEMS

KW - MASS-METALLICITY RELATION

KW - DAMPED LYMAN

KW - MOLECULAR-HYDROGEN

KW - INTERSTELLAR ABUNDANCES

KW - ELEMENTAL ABUNDANCES

KW - DEPLETION PATTERN

KW - DWARF GALAXIES

KW - EVOLUTION

KW - CLOUD

U2 - 10.1051/0004-6361/202244609

DO - 10.1051/0004-6361/202244609

M3 - Journal article

VL - 672

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

SN - 0004-6361

M1 - A68

ER -

ID: 347878322