ALMA 200 pc Resolution Imaging of Smooth Cold Dusty Disks in Typical z ∼ 3 Star-forming Galaxies

Rujopakarn, W.; Daddi, E.; Rieke, G. H.; Puglisi, A.; Schramm, Malte; Pérez‐González, Pablo G.; Magdis, G.; Alberts, Stacey; Bournaud, F.; Elbaz, D.; Franco, Maximilien; Kawinwanichakij, Lalitwadee; Kohno, Kotaro; Narayanan, Desika; Silverman, John D.; Wang, T.; Williams, Christina C.

doi:10.3847/1538-4357/ab3791

Cited by 79 publications

(91 citation statements)

References 173 publications

(266 reference statements)

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“…Noises could be potentially amplified by deconvolution if the clean is not perfect. We make the same analysis of a dirty cube to check if the results do not depend on the clean (Rujopakarn et al 2019). Figure 8 shows residual channel maps of the dirty cube.…”

Section: Analysis Of Dirty Imagesmentioning

confidence: 99%

A Noncorotating Gas Component in an Extreme Starburst at z = 4.3

Tadaki

Iono

Yun

et al. 2020

ApJ

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We report the detection of a non-corotating gas component in a bright unlensed submillimeter galaxy at z = 4.3, COSMOS-AzTEC-1, hosting a compact starburst. ALMA 0.17 and 0.09 arcsec resolution observations of [C ii] emission clearly demonstrate that the gas kinematics is characterized by an ordered rotation. After subtracting the best-fit model of a rotating disk, we kinematically identify two residual components in the channel maps. Both observing simulations and analysis of dirty images confirm that these two subcomponents are not artificially created by noise fluctuations and beam deconvolution. One of the two has a velocity offset of 200 km s −1 and a physical separation of 2 kpc from the primary disk and is located along the kinematic minor axis of disk rotation. We conclude that this gas component is falling into the galaxy from a direction perpendicular to the disk rotation. The accretion of such small non-corotating gas components could stimulate violent disk instability, driving radial gas inflows into the center of galaxies and leading to formation of in-situ clumps such as identified in dust continuum and CO. We require more theoretical studies on high gas fraction mergers with mass ratio of 1:> 10 to verify this process.

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Section: Analysis Of Dirty Imagesmentioning

confidence: 99%

A Noncorotating Gas Component in an Extreme Starburst at z = 4.3

Tadaki

Iono

Yun

et al. 2020

ApJ

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“…Actually, the structure of high-z ETG starforming progenitors is more complex. On kpc scales, both observations (e.g., Genzel et al 2011;Tadaki et al 2017aTadaki et al ,b, 2018Hodge et al 2019;Lang et al 2019;Rujopakarn et al 2019) and simulations (e.g., Bournaud et al 2014;Mandelker et al 2014Mandelker et al , 2017Oklopcic et al 2017) indicate the presence of clumps with masses 10 7 − 10 8 M and sizes of 100 − 200 kpc; note that even more massive and extended clumps can be present but are rarer, and could be real outcomes from collisions of smaller ones (e.g., Tamburello et al 2015) or apparent structures due to blending from observations with limited resolution (e.g., Tamburello et al 2017;Behrend et al 2016;Faure et al 2019, in preparation). The survival of the clumps is still a debated issue, with different simulations favoring short-lived clumps because of feedback and/or collisions (e.g., Hopkins et al 2012;Oklopcic et al 2017), or long-lived clumps that may eventually sink toward the center via gravitational torque and bar instabilities and contribute to the growth of a central bulge (e.g., Ceverino et al 2012;Bournaud et al 2014).…”

Section: Discussionmentioning

confidence: 96%

“…On a scale of a few kpc, the velocity structure is dominated by rotational motions with v/σ a few, in the way of a clumpy unstable disk (see Genzel et al 2011;Tadaki et al 2017aTadaki et al ,b, 2018Hodge et al 2019). However, on sub-kpc scales both observations (e.g., Barro et al 2016;Rujopakarn et al 2019) and simulations (e.g., Danovich et al 2015;Zolotov et al 2015;Zavala et al 2016) indicate that dynamical friction, gravitational torques, and violent relaxation will operate toward converting such rotational into random motions, setting up a bulge-like structure with v/σ 1 (see also Lapi et al 2018). Provided that the majority of the compact remnants contributing to the growth of the central seed BH come from a scale of 300 pc, our assumption of a dispersion-dominated velocity structure should hold to a good approximation.…”

Section: Discussionmentioning

confidence: 99%

“…Indubitably, the presence of such a clumpiness in the gaseous medium may in principle affect the dynamical evolution of the rem-nants. However, high-resolution observations with ALMA (see Hodge et al 2019;Rujopakarn et al 2019) have revealed that such clumps contribute less than 10% of the overall star-formation; the latter mainly occurs in a rather smooth gaseous and dust-enshrouded medium within the central kpc scale. Provided that in our treatment most of the compact remnants effectively contributing to the growth of the central BH seed come from initial radii of 300 pc, the assumption of a smooth distribution for the inner star-forming gas should hold to a good approximation.…”

Section: Discussionmentioning

confidence: 99%

“…• Dust component. The central kpc regions of a star-forming ETG progenitors are very dusty (e.g., Tadaki et al 2017aTadaki et al ,b, 2018Hodge et al 2019;Rujopakarn et al 2019). In principle, dust can cooperate with the gas component in making the dynamical friction of the compact remnants more efficient, and speed up the building up of the central BH seed.…”

Section: Discussionmentioning

confidence: 99%

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Growth of Supermassive Black Hole Seeds in ETG Star-forming Progenitors: Multiple Merging of Stellar Compact Remnants via Gaseous Dynamical Friction and Gravitational-wave Emission

Boco

Lapi

Danese

2020

ApJ

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We propose a new mechanism for the growth of supermassive black hole (BH) seeds in the starforming progenitors of local early-type galaxies (ETGs) at z 1. This envisages the migration and merging of stellar compact remnants (neutron stars and stellar-mass BHs) via gaseous dynamical friction toward the central high-density regions of such galaxies. We show that, under reasonable assumptions and initial conditions, the process can build up central BH masses of order 10 4 − 10 6 M within some 10 7 yr, so effectively providing heavy seeds before standard disk (Eddington-like) accretion takes over to become the dominant process for further BH growth. Remarkably, such a mechanism may provide an explanation, alternative to super-Eddington accretion rates, for the buildup of billion solar masses BHs in quasar hosts at z 7, when the age of the Universe 0.8 Gyr constitutes a demanding constraint; moreover, in more common ETG progenitors at redshift z ∼ 2−6 it can concur with disk accretion to build such large BH masses even at moderate Eddington ratios 0.3 within the short star-formation duration Gyr of these systems. Finally, we investigate the perspectives to detect the merger events between the migrating stellar remnants and the accumulating central supermassive BH via gravitational wave emission with future ground and space-based detectors such as the Einstein Telescope (ET) and the Laser Interferometer Space Antenna (LISA).

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