Direct T
               <sub>e</sub>-based Metallicities of z = 2–9 Galaxies with JWST/NIRSpec: Empirical Metallicity Calibrations Applicable from Reionization to Cosmic Noon

Sanders, Ryan L.; Shapley, Alice E.; Topping, Michael W.; Reddy, Naveen A.; Brammer, Gabriel B.

doi:10.3847/1538-4357/ad15fc

Cited by 25 publications

(9 citation statements)

References 108 publications

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“…The O/H abundance measured in D40, 12+log(O/H) = 8.07 ± 0.06 dex, is indicative of a relatively metal-poor ISM. While this is lower than the average model-inferred metallicity of the KBSS galaxies reported in Strom et al (2018), D40ʼs O/H is consistent with its relatively high T e [O III] and T e [S III] and is in general agreement with emerging direct O/H abundance trends at z > 1 (e.g., Sanders et al 2024;Welch et al 2024). In the top panel, the inferred log(N/O) abundance in D40 (green circle; −1.37 ± 0.21 dex) is in good agreement with the primary N/O plateau (log(N/O) ∼ −1.43 dex; Garnett 1990;Nava et al 2006;van Zee & Haynes 2006) established by high-ionization, low-metallicity dwarf galaxies and H II regions.…”

Section: Abundance Resultssupporting

confidence: 73%

“…However, with the NIR capabilities of the James Webb Space Telescope (JWST), direct T e measurements and abundances are now readily accessible in high-z galaxies (e.g., Arellano-Córdova et al 2022a;Schaerer et al 2022;Sanders et al 2024;Laseter et al 2024;Trump et al 2023;Topping et al 2024;Welch et al 2024). While these studies have started to uncover the chemical abundance patterns in the early Universe, the current scope of high-z chemical abundances is still fairly limited.…”

Section: Introductionmentioning

confidence: 99%

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CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at z ∼ 3

Rogers,

Strom,

Rudie

et al. 2024

ApJL

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Measurements of chemical abundances in high-z star-forming (SF) galaxies place important constraints on the enrichment histories of galaxies and the physical conditions in the early Universe. The James Webb Space Telescope (JWST) is beginning to enable direct chemical abundance measurements in galaxies at z > 2 via the detection of the faint T e -sensitive auroral line [O iii] λ4364. However, abundances of other elements (e.g., S and Ar) in high-z galaxies remain unconstrained owing to a lack of T e data and wavelength coverage. Here we present multiple direct abundances in Q2343-D40, a galaxy at z = 2.9628 ± 0.0001 observed with JWST/NIRSpec as part of the CECILIA program. We report the first simultaneous measurement of T e [O iii] and T e [S iii] in a high-z galaxy, finding good agreement with the temperature trends in local SF systems. We measure a gas-phase metallicity of 12+log(O/H) = 8.07 ± 0.06, and the N/O abundance, log(N/O) = −1.37 ± 0.21, is indicative of primary nucleosynthesis. The S/O and Ar/O relative abundances, log(S/O) = −1.88 ± 0.10 and log(Ar/O) = −2.80 ± 0.12, are both >0.3 dex lower than the solar ratios. However, the relative Ar2+/S2+ abundance is consistent with the solar ratio, suggesting that the relative S-to-Ar abundance does not evolve significantly with redshift. Recent nucleosynthesis models find that significant amounts of S and Ar are produced in Type Ia supernovae, such that the S/O and Ar/O abundances in Q2343-D40 could be the result of predominantly core-collapse supernova enrichment. Future JWST observations of high-z galaxies will uncover whether S/O and Ar/O are sensitive to the timescales of these different enrichment mechanisms.

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Section: Abundance Resultssupporting

confidence: 73%

Section: Introductionmentioning

confidence: 99%

CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at z ∼ 3

Rogers,

Strom,

Rudie

et al. 2024

ApJL

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“…As the archive of deep, high-redshift observations with JWST grows, and the quality of the data calibrations steadily improve, emission-line calibrations are being expanded to a vastly increased parameter space in a robust, self-consistent manner. Progress is already being made in this area with revised calibrations proposed by Sanders et al (2024), Hirschmann et al (2023, and additional studies (Nakajima et al 2022;Garg et al 2023;Yang et al 2023). This rapid release of results related to the metallicities of galaxies across cosmic time should provide a consensus on these issues that was not possible before JWST (e.g., Langeroodi et al 2022;Atek et al 2023;Curti et al 2023;Heintz et al 2023;Langeroodi & Hjorth 2023;Maseda et al 2023;Matthee et al 2023;Shapley et al 2023;Sun et al 2023;Trump et al 2023;Bagley et al 2024).…”

Section: Discussionmentioning

confidence: 99%

The MUSE Ultra Deep Field (MUDF). V. Characterizing the Mass–Metallicity Relation for Low-mass Galaxies at z ∼ 1–2

Revalski,

Rafelski,

Henry

et al. 2024

ApJ

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Using more than 100 galaxies in the MUSE Ultra Deep Field with spectroscopy from the Hubble Space Telescope’s (HST) Wide Field Camera 3 and the Very Large Telescope’s Multi Unit Spectroscopic Explorer, we extend the gas-phase mass–metallicity relation (MZR) at z ≈ 1–2 down to stellar masses of M ⋆ ≈ 107.5 M ⊙. The sample reaches 6 times lower in stellar mass and star formation rate (SFR) than previous HST studies at these redshifts, and we find that galaxy metallicities decrease to log(O/H) + 12 ≈ 7.8 ± 0.1 (15% solar) at log(M ⋆/M ⊙) ≈ 7.5, without evidence of a turnover in the shape of the MZR at low masses. We validate our strong-line metallicities using the direct method for sources with [O iii] λ4363 and [O iii] λ1666 detections, and find excellent agreement between the techniques. The [O iii] λ1666-based metallicities double existing measurements with a signal-to-noise ratio ≥ 5 for unlensed sources at z > 1, validating the strong-line calibrations up to z ∼ 2.5. We confirm that the MZR resides ∼0.3 dex lower in metallicity than local galaxies and is consistent with the fundamental metallicity relation if the low-mass slope varies with SFR. At lower redshifts (z ∼ 0.5) our sample reaches ∼0.5 dex lower in SFR than current calibrations and we find enhanced metallicities that are consistent with extrapolating the MZR to lower SFRs. Finally, we detect only an ∼0.1 dex difference in the metallicities of galaxies in groups versus isolated environments. These results are based on robust calibrations and reach the lowest masses and SFRs that are accessible with HST, providing a critical foundation for studies with the Webb and Roman Space Telescopes.

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“…Fortunately, the launch of JWST has considerably augmented the data set of high-redshift galaxies available for calibration purposes (e.g., Heintz et al 2023;Laseter et al 2024;Sanders et al 2024), bringing us closer to the direct calibration of strong methods in high-redshift galaxies.…”

Section: Strong-line Estimatementioning

confidence: 99%

“…The existing set of galaxies with detected auroral lines comprises approximately 20 targets within the redshift range of 1.6 < z < 3.6 (e.g., Yuan & Kewley 2009;Christensen et al 2012aChristensen et al , 2012bBayliss et al 2014;James et al 2014;Stark et al 2014;Berg et al 2018;Gburek et al 2019;Sanders et al 2020). However, the advent of the James Webb Space Telescope (JWST) has significantly expanded this data set, allowing for detections at redshifts up to approximately z ∼ 8 (e.g., Heintz et al 2023;Laseter et al 2024;Sanders et al 2024).…”

Section: Introductionmentioning

confidence: 99%

A Comprehensive Metallicity Analysis of J0332−3557: Establishing a z ∼ 4 Anchor for Direct Gas Metallicity and C/O Abundance Investigations

Citro,

Berg,

Erb

et al. 2024

ApJ

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We provide one of the most comprehensive metallicity studies at z ∼ 4 by analyzing the UV/optical Hubble Space Telescope photometry and rest-frame Very Large Telescope (VLT)/FORS2 UV and VLT/XSHOOTER optical spectra of J0332−3557, a gravitationally lensed galaxy magnified by a factor of 20. With a 5σ detection of the auroral O iii] λ1666 line, we are able to derive a direct gas metallicity estimate for our target. We find Z gas = 12 + log ( O / H ) = 8.26 ± 0.06 , which is compatible with an increase of both the gas fraction and the outflow metal loading factor from z ∼ 0 to z ∼ 4. J0332−3557 is the most metal-rich individual galaxy at z ∼ 4 for which the C/O ratio has been measured. We derive a low log(C/O) = −1.02 ± 0.2, which suggests that J0332−3557 is in the early stages of interstellar medium carbon enrichment driven mostly by massive stars. The low C/O abundance also indicates that J0332−3557 is characterized by a low star formation efficiency, higher yields of oxygen, and longer burst duration. We find that EWC III]1906,9 is as low as ∼3 Å, and the main drivers of the low EWC III]1906,9 are the higher gas metallicity and the low C/O abundance. J0332−3557 is characterized by one diffuse and two more compact regions ∼1 kpc in size. We find that the carbon emission mostly originates in the compact knots. Our study on J0332−3557 serves as an anchor for studies investigating the evolution of metallicity and C/O abundance across different redshifts.

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Direct T _e-based Metallicities of z = 2–9 Galaxies with JWST/NIRSpec: Empirical Metallicity Calibrations Applicable from Reionization to Cosmic Noon

Cited by 25 publications

References 108 publications

CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at z ∼ 3

CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at z ∼ 3

The MUSE Ultra Deep Field (MUDF). V. Characterizing the Mass–Metallicity Relation for Low-mass Galaxies at z ∼ 1–2

A Comprehensive Metallicity Analysis of J0332−3557: Establishing a z ∼ 4 Anchor for Direct Gas Metallicity and C/O Abundance Investigations

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Direct T e-based Metallicities of z = 2–9 Galaxies with JWST/NIRSpec: Empirical Metallicity Calibrations Applicable from Reionization to Cosmic Noon

Cited by 25 publications

References 108 publications

CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at z ∼ 3

CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at z ∼ 3

The MUSE Ultra Deep Field (MUDF). V. Characterizing the Mass–Metallicity Relation for Low-mass Galaxies at z ∼ 1–2

A Comprehensive Metallicity Analysis of J0332−3557: Establishing a z ∼ 4 Anchor for Direct Gas Metallicity and C/O Abundance Investigations

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Direct T _e-based Metallicities of z = 2–9 Galaxies with JWST/NIRSpec: Empirical Metallicity Calibrations Applicable from Reionization to Cosmic Noon