The ALMA-ALPAKA survey

Rizzo, F.; Roman-Oliveira, F.; Fraternali, F.; Frickmann, D.; Valentino, F. M.; Brammer, G.; Zanella, A.; Kokorev, V.; Popping, G.; Whitaker, K. E.; Kohandel, M.; Magdis, G. E.; Di Mascolo, L.; Ikeda, R.; Jin, S.; Toft, S.

doi:10.1051/0004-6361/202346444

Cited by 15 publications

(5 citation statements)

References 209 publications

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“…In agreement with our assessment given above, PACS-819 has kinematic properties broadly consistent with a rotating disk, which is typical for high-z star-forming galaxies (Übler et al 2018;Förster Schreiber et al 2018;Johnson et al 2018;Wisnioski et al 2019). Our conclusions align with the results presented by Rizzo et al (2023), which characterize this galaxy as rotation dominated (V rot /σ gas > 6-7) and with notable noncircular features. Such a feature can be spotted in the region pointed out by the brown arrow in Figure 9.…”

Section: Model Kinematic Fittingsupporting

confidence: 91%

“…Such a feature can be spotted in the region pointed out by the brown arrow in Figure 9. The gas there is moving slower than the disk rotation predicted by the model, which is interpreted as inflowing or outflowing extraplanar gas in Rizzo et al (2023).…”

Section: Model Kinematic Fittingmentioning

confidence: 77%

“…Also, there is a distinct anomaly seen in the velocity and dispersion maps at the position of the blueshifted component (Figure 7(b)) that is cospatial with the "green" JWST component in the RGB image (Figure 3) and likely indicating the existence of a distinct "clump." Rizzo et al (2023) analyze the velocity anomalies of PACS-819 in detail and conclude that these anomalies are noncircular features rotating faster or slower than the disk. These features can also be spotted on the maps constructed by our independent study, as shown by the arrow (Figure 9).…”

Section: Model Kinematic Fittingmentioning

confidence: 99%

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JWST and ALMA Discern the Assembly of Structural and Obscured Components in a High-redshift Starburst Galaxy

Liu,

Silverman,

Daddi

et al. 2024

ApJ

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We present observations and analysis of the starburst PACS-819 at z = 1.45 (M * = 1010.7 M ⊙), using high-resolution (0.″1; 0.8 kpc) Atacama Large Millimeter/submillimeter Array (ALMA) and multiwavelength JWST images from the COSMOS-Web program. Dissimilar to Hubble Space Telescope (HST) ACS images in the rest-frame UV, the redder NIRCam and MIRI images reveal a smooth central mass concentration and spiral-like features, atypical for such an intense starburst. Through dynamical modeling of the CO (J = 5–4) emission with ALMA, PACS-819 is rotation dominated and thus consistent with having a disk-like nature. However, kinematic anomalies in CO and asymmetric features in the bluer JWST bands (e.g., F150W) support a more disturbed nature likely due to interactions. The JWST imaging further enables us to map the distribution of stellar mass and dust attenuation, thus clarifying the relationships between different structural components not discernible in the previous HST images. The CO (J = 5–4) and far-infrared dust continuum emission are cospatial with a heavily obscured starbursting core (<1 kpc) that is partially surrounded by much less obscured star-forming structures including a prominent arc, possibly a tidally distorted dwarf galaxy, and a massive clump (detected in CO), likely a recently accreted low-mass satellite. With spatially resolved maps, we find a high molecular gas fraction in the central area reaching ∼3 (M gas/M *) and short depletion times (M gas/SFR ∼ 120 Myr, where SFR is star formation rate) across the entire system. These observations provide insights into the complex nature of starbursts in the distant Universe and underscore the wealth of complementary information from high-resolution observations with both ALMA and JWST.

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Section: Model Kinematic Fittingsupporting

confidence: 91%

Section: Model Kinematic Fittingmentioning

confidence: 77%

Section: Model Kinematic Fittingmentioning

confidence: 99%

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JWST and ALMA Discern the Assembly of Structural and Obscured Components in a High-redshift Starburst Galaxy

Liu,

Silverman,

Daddi

et al. 2024

ApJ

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“…The mass assembly of galaxies is dominated by two processes: steady cold accretion (Kereš et al 2005) and mergers (Hopkins et al 2010). While steady cold accretion tends to produce systems with stable disks (Förster Schreiber & Wuyts 2020; Rizzo et al 2023), mergers and counterrotating gas inflows may disrupt galactic structure. Generally speaking, SFGs are less likely to host rotation-dominated disks as we push to lower stellar masses and earlier epochs (Förster Schreiber & Wuyts 2020).…”

Section: Introductionmentioning

confidence: 99%

“…This is an unsurprising result; lowmass systems are easier to disrupt, and the harsher conditions of the early Universe increase the efficacy of disruptive processes (e.g., Pillepich et al 2019). However, a number of dynamically cold disks have still been observed in the highredshift regime (e.g., Rizzo et al 2020Rizzo et al , 2021Rizzo et al , 2022Rizzo et al , 2023Jones et al 2021;Roman-Oliveira et al 2023).…”

Section: Introductionmentioning

confidence: 99%

First Constraints on the Interstellar Medium Conditions of a Low-mass, Highly Obscured z = 4.27 Main-sequence Galaxy

Mizener,

Pope,

McKinney

et al. 2024

ApJ

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We present the molecular gas content and interstellar medium conditions of MACS J0717_Az9, a strong gravitationally lensed z = 4.273, M * ≃ 2 × 109 M ⊙ star-forming galaxy with an unusually high (∼80%) obscured star formation fraction. We detect CO (4–3) in two independent lensed images, as well as [N ii] 205 μm, with the Atacama Large Millimeter Array. We derive a molecular gas mass of log 10 [ M H 2 ( M ⊙ ) ] = 9.77 , making it moderately deficient in molecular gas compared to the lower-redshift gas fraction scaling relation. Leveraging photodissociation region (PDR) models, we combine our CO (4–3) measurements with existing measurements of the [C ii] 158 μm line and total infrared luminosity to model the PDR conditions. We find PDR conditions similar to those in local star-forming galaxies, with a mean hydrogen density log10[n H cm−3] = 4.80 ± 0.39 and a mean radiation field strength log10[G 0 Habing] = 2.83 ± 0.26. Based on Band 3 continuum data, we derive an upper limit on the intrinsic dust mass of log10[M dust(M ⊙)] < 7.73, consistent with existing estimates. We use the 3D tilted-ring model fitting code 3D-Barolo to determine the kinematic properties of the CO (4–3) emitting gas. We find that it is rotationally dominated, with a V/σ = 4.6 ± 1.7, consistent with the kinematics of the [C ii]. With PDR conditions remarkably similar to those in normal dusty star-forming galaxies at z < 0.2 and a stable molecular disk, our observations of Az9 suggest that the dust-obscured phase for a low-mass galaxy at z ∼ 4 is relatively long. Thus, Az9 may be representative of a more widespread population that has been missed owing to insufficiently deep existing millimeter surveys.

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