JWST’s PEARLS: Resolved study of the stellar and dust components in starburst galaxies at cosmic noon

Polletta, M.; Frye, B. L.; Garuda, N.; Willner, S. P.; Berta, S.; Kneissl, R.; Dole, H.; Jansen, R. A.; Lehnert, M. D.; Cohen, S. H.; Summers, J.; Windhorst, R. A.; D’Silva, J. C. J.; Koekemoer, A. M.; Coe, D.; Conselice, C. J.; Driver, S. P.; Grogin, N. A.; Marshall, M. A.; Nonino, M.; Ortiz III, R.; Pirzkal, N.; Robotham, A.; Ryan, R. E.; Willmer, C. N. A.; Yan, H.; Arumugam, V.; Cheng, C.; Gim, H. B.; Hathi, N. P.; Holwerda, B.; Kamieneski, P.; Keel, W. C.; Li, J.; Pascale, M.; Rottgering, H.; Smith, B. M.; Yun, M. S.

doi:10.1051/0004-6361/202450671

A&A

2024

DOI: 10.1051/0004-6361/202450671

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JWST’s PEARLS: Resolved study of the stellar and dust components in starburst galaxies at cosmic noon

M. Polletta,

B. L. Frye,

N. Garuda

et al.

Abstract: Dusty star-forming galaxies (DSFGs) significantly contribute to the stellar buildup in galaxies during ``cosmic noon,'' the peak epoch of cosmic star formation. Major mergers and gas accretion are often invoked to explain DSFGs' prodigious star formation rates (SFRs) and large stellar masses. We conducted a spatially resolved morphological analysis of the rest-frame ultraviolet/near-infrared (sim 0.25--1.3mu m) emission in three DSFGs at $z Initially discovered as carbon monoxide (CO) emitters by NOrthern Ext… Show more

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Cited by 2 publications

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The structure of massive star-forming galaxies from JWST and ALMA: Dusty, high-redshift disc galaxies

Gillman,

Smail,

Gullberg

et al. 2024

A&A

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We present an analysis of the NIRCam and MIRI morphological and structural properties of 80 massive ($ (M_ M_ odot )$\,=\,11.2\,pm \,0.1) dusty star-forming galaxies at $, identified as sub-millimetre galaxies (SMGs) by ALMA, which have been observed as part of the PRIMER project. To compare the structure of these massive, active galaxies to more typical, less actively star-forming galaxies, we defined two comparison samples. The first of 850 field galaxies matched in specific star formation rate and redshift and the second of 80 field galaxies matched in stellar mass . From the visual classification of the SMGs, we have identified 20\,pm \,5<!PCT!> as candidate late-stage major mergers, a further 40\,pm \,10<!PCT!> as potential minor mergers, and 40\,pm \,10<!PCT!> that have comparatively undisturbed disc-like morphologies, with no obvious massive neighbours on lesssim \,20\,--\,30\,kpc (projected) scales. These rates are comparable to those for the field samples and indicate that the majority of the sub-millimetre-detected galaxies are not late-stage major mergers, but have interaction rates similar to the general field population at $z$\,sim \,2--3. Through a multi-wavelength morphological analysis, using parametric and non-parametric techniques, we establish that SMGs have comparable near-infrared, mass-normalised sizes to the less active population, $ F444W $\,=\,2.7\,pm \,0.2\,kpc versus $ F444W $\,=\,3.1\,pm \,0.1\,kpc, but exhibit lower S\'ersic indices, consistent with bulge-less discs: F444W $\,=\,1.1\,pm \,0.1, compared to F444W $\,=\,1.9\,pm \,0.1 for the less active field galaxies and $n_ F444W $\,=\,2.8\,pm \,0.2 for the most massive field galaxies . The SMGs exhibit greater single-S\'ersic fit residuals and their morphologies are more structured at 2 relative to 4 when compared to the field galaxies. This appears to be caused by significant structured dust content in the SMGs and we find evidence for dust reddening as the origin of the morphological differences by identifying a strong correlation between the F200W$-$F444W pixel colour and the 870 surface brightness using high-resolution ALMA observations. We conclude that SMGs and both massive and less massive star-forming galaxies at the same epochs share a common disc-like structure, but the weaker bulge components (and potentially lower black hole masses) of the SMGs result in their gas discs being less stable. Consequently, the combination of high gas masses and instabilities triggered either secularly or by minor external perturbations results in higher levels of activity (and dust content) in SMGs compared to typical star-forming galaxies.

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The structure of massive star-forming galaxies from JWST and ALMA: Dusty, high-redshift disc galaxies

Gillman,

Smail,

Gullberg

et al. 2024

A&A

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JWST/NIRCam Paβ Narrowband Imaging Reveals Ordinary Dust Extinction for Hα Emitters within the Spiderweb Protocluster at z = 2.16

Pérez-Martínez,

Dannerbauer,

Koyama

et al. 2024

ApJ

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We combine JWST/NIRCam and Subaru/MOIRCS dual Paβ+Hα narrowband imaging to trace the dust attenuation and the star formation activities of a sample of 43 Hα emitters at the core of one of the most massive and best-studied clusters in formation at the cosmic noon: the Spiderweb protocluster at z = 2.16. We find that most Hα emitters display Paβ/Hα ratios compatible with Case B recombination conditions, which translates into nebular extinction values ranging at AV ≈ 0–3 mag, and dust corrected Paβ star formation rates consistent with coeval main sequence field galaxies at fixed stellar mass ( 9.4 < log M * / M ⊙ < 11.0 ) during this cosmic epoch. Furthermore, we investigate possible environmental impacts on dust extinction across the protocluster large-scale structure and find no correlation between the dustiness of its members and environmental proxies such as phase-space position, clustercentric radius, or local density. These results support the scenario for which dust production within the main galaxy population of this protocluster is driven by secular star formation activities fueled by smooth gas accretion across its large-scale structure. This downplays the role of gravitational interactions in boosting star formation and dust production within the Spiderweb protocluster, in contrast with observations in higher redshift and less evolved protocluster cores.

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JWST’s PEARLS: Resolved study of the stellar and dust components in starburst galaxies at cosmic noon

Cited by 2 publications

References 274 publications

The structure of massive star-forming galaxies from JWST and ALMA: Dusty, high-redshift disc galaxies

The structure of massive star-forming galaxies from JWST and ALMA: Dusty, high-redshift disc galaxies

JWST/NIRCam Paβ Narrowband Imaging Reveals Ordinary Dust Extinction for Hα Emitters within the Spiderweb Protocluster at z = 2.16

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