MUSE Analysis of Gas around Galaxies (MAGG) – II: metal-enriched halo gas around <i>z</i> ∼ 1 galaxies

Dutta, Rajeshwari; Fumagalli, Michele; Fossati, M.; Lofthouse, Emma K.; Prochaska, J. Xavier; Battaia, Fabrizio Arrigoni; Bielby, R. M.; Cantalupo, Sebastiano; Cooke, Ryan; Murphy, Michael T.; O’Meara, John M.

doi:10.1093/mnras/staa3147

Cited by 61 publications

(116 citation statements)

References 151 publications

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“…Next, we derived the stellar mass and star formation rate (SFR) of the sources using the Monte Carlo Spectro-Photometric Fitter (MC-SPF; Fossati et al 2018). We follow the procedure described in Fossati et al (2019b) and Dutta et al (2020). In brief, we use stellar population models from Bruzual & Charlot (2003) at solar metallicity, nebular emission lines from the models of Byler et al (2018), and the initial mass function (IMF) from Chabrier (2003).…”

Section: Qsage Galaxy Surveymentioning

confidence: 99%

“…For example, the Mg II doublet lines have long been used to trace the cool (T ∼ 10 4 K) and low-ionization (ionization potential, IP = 15.0 eV) gas (e.g. Lanzetta & Bowen 1990;Steidel & Sargent 1992;Churchill et al 2000;Chen et al 2010;Nielsen, Churchill & Kacprzak 2013;Zhu & Ménard 2013;Dutta et al 2020), while the C IV doublet lines on the other hand have been used extensively to trace the potentially warmer (T ∼ 10 5 K) and high-ionization (IP = 64.5 eV) gas (e.g. Sargent, Boksenberg & Steidel 1988;Chen, Lanzetta & Webb 2001;Schaye et al 2003;Cooksey et al 2013;Bordoloi et al 2014;Burchett et al 2016).…”

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confidence: 99%

“…Further, there have been studies of the cool gas traced by Mg II absorption in individual groups and clusters (Whiting, Webster & Francis 2006;Lopez et al 2008;Kacprzak, Murphy & Churchill 2010;Gauthier 2013). Recently, with the advent of widefield optical integral field unit (IFU) spectrographs like the Multi Unit Spectroscopic Explorer (MUSE; Bacon et al 2010) on the Very Large Telescope (VLT), there have been several identifications of groups associated with cool gas as traced by Mg II absorption (Bielby et al 2017a;Fumagalli et al 2017;Péroux et al 2017Péroux et al , 2019Chen et al 2019;Fossati et al 2019b;Dutta et al 2020;Hamanowicz et al 2020). With a more complete identification of the small-scale galaxy environment and the galaxy population down to a fixed flux limit across the entire field of view (FoV), such studies suggest that environmental interactions play a role in enhancing the cross-section of Mg II absorbing gas around galaxies in groups (Fossati et al 2019b;Dutta et al 2020).…”

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confidence: 99%

“…In this work, we study gaseous haloes up to z ≈ 2 with a systematic focus on the galaxy environment, taking advantage of the large and complete galaxy surveys that are becoming available now in quasar fields. In particular, we use data from two large, independent surveys -the MUSE Analysis of Gas around Galaxies (MAGG; Dutta et al 2020;Lofthouse et al 2020;Fossati et al 2021) survey and the Quasar Sightline and Galaxy Evolution (QSAGE; Bielby et al 2019;Stott et al 2020) survey. The structure of this paper is as follows.…”

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confidence: 99%

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Metal-enriched halo gas across galaxy overdensities over the last 10 billion years

Dutta

Fumagalli

Fossati

et al. 2021

Monthly Notices of the Royal Astronomical Society

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We present a study of metal-enriched halo gas traced by Mg ii and C iv absorption at z < 2 in the MUSE Analysis of Gas around Galaxies survey and the Quasar Sightline and Galaxy Evolution survey. Using these large and complete galaxy surveys in quasar fields, we study the dependence of the metal distribution on galaxy properties and overdensities, out to physical projected separations of 750 kpc. We find that the cool, low-ionization gas is significantly affected by the environment across the full redshift range probed, with ≈2 − 3 times more prevalent and stronger Mg ii absorption in higher overdensity group environments and in regions with greater overall stellar mass and star formation rates. Complementary to these results, we have further investigated the more highly ionized gas as traced by C iv absorption, and found that it is likely to be more extended than the Mg ii gas, with ≈2 times higher covering fraction at a given distance. We find that the strength and covering fraction of C iv absorption show less significant dependence on galaxy properties and environment than the Mg ii absorption, but more massive and star-forming galaxies nevertheless also show ≈2 times higher incidence of C iv absorption. The incidence of Mg ii and C iv absorption within the virial radius shows a tentative increase with redshift, being higher by a factor of ≈1.5 and ≈4, respectively, at z > 1. It is clear from our results that environmental processes have a significant impact on the distribution of metals around galaxies and need to be fully accounted for when analyzing correlations between gaseous haloes and galaxy properties.

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Section: Qsage Galaxy Surveymentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Metal-enriched halo gas across galaxy overdensities over the last 10 billion years

Dutta

Fumagalli

Fossati

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…The main goal of MAGG is the study of the CGM of z = 3-4.5 star-forming galaxies in the surroundings of H I absorbers with log N H I 10 17 cm −2 (Lofthouse et al, in preparation). The rich MAGG data sets are further being utilized to study the cold CGM gas around z ∼ 1 galaxies (Dutta et al 2020), and near z = 3-4.5 quasars, which is the subject of this work.…”

Section: Introductionmentioning

confidence: 99%

MUSE analysis of gas around galaxies (MAGG) – III. The gas and galaxy environment of z = 3–4.5 quasars

Fossati

Fumagalli

Lofthouse

et al. 2021

Monthly Notices of the Royal Astronomical Society

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We present a study of the environment of 27 z = 3 − 4.5 bright quasars from the MUSE Analysis of Gas around Galaxies (MAGG) survey. With medium-depth MUSE observations (4 hours on target per field), we characterise the effects of quasars on their surroundings by studying simultaneously the properties of extended gas nebulae and Lyα emitters (LAEs) in the quasar host haloes. We detect extended (up to ≈100 kpc) Lyα emission around all MAGG quasars, finding a very weak redshift evolution between z = 3 and z = 6. By stacking the MUSE datacubes, we confidently detect extended emission of C iv and only marginally detect extended He ii up to ≈40 kpc, implying that the gas is metal enriched. Moreover, our observations show a significant overdensity of LAEs within 300 $\rm km~s^{-1}$ from the quasar systemic redshifts estimated from the nebular emission. The luminosity functions and equivalent width distributions of these LAEs show similar shapes with respect to LAEs away from quasars suggesting that the Lyα emission of the majority of these sources is not significantly boosted by the quasar radiation or other processes related to the quasar environment. Within this framework, the observed LAE overdensities and our kinematic measurements imply that bright quasars at z = 3 − 4.5 are hosted by haloes in the mass range $\approx 10^{12.0}-10^{12.5}~\rm M_\odot$.

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Probing galaxy evolution through Hi 21-cm emission and absorption: current status and prospects with square kilometre array

et al. 2022

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One of the major science goals of square kilometre array (SKA) is to understand the role played by atomic hydrogen (Hi) gas in the evolution of galaxies throughout cosmic time. The hyperfine transition line of the hydrogen atom at 21-cm is one of the best tools to detect and study the properties of Hi gas associated with galaxies. In this paper, we review our current understanding of Hi gas and its relationship with galaxies through observations of the 21-cm line both in emission and absorption. In addition, we provide an overview of the Hi science that will be possible with SKA and its precursors and pathfinders, i.e., Hi 21-cm emission and absorption studies of galaxies from nearby to high redshifts that will trace various processes governing galaxy evolution.

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MUSE Analysis of Gas around Galaxies (MAGG) – II: metal-enriched halo gas around z ∼ 1 galaxies

Cited by 61 publications

References 151 publications

Metal-enriched halo gas across galaxy overdensities over the last 10 billion years

Metal-enriched halo gas across galaxy overdensities over the last 10 billion years

MUSE analysis of gas around galaxies (MAGG) – III. The gas and galaxy environment of z = 3–4.5 quasars

Probing galaxy evolution through Hi 21-cm emission and absorption: current status and prospects with square kilometre array

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