Compact Star-forming Galaxies as Old Starbursts Becoming Quiescent

Gómez-Guijarro, Carlos; Magdis, G.; Valentino, F.; Toft, Sune; Man, Allison; Ivison, R. J.; Tisanić, Krešimir; Vlugt, D. van der; Stockmann, Mikkel; Martin-Alvarez, Sergio; Brammer, Gabriel

doi:10.3847/1538-4357/ab418b

Cited by 36 publications

(48 citation statements)

References 98 publications

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“…This proved to be a useful distinction and an excellent predictor of several trends (e.g., Sargent et al 2014), but recent results, including our present and previous analysis (Puglisi et al 2019), show that the demarcation between starburst and main-sequence galaxies is more blurred that we previously considered. We do detect starburst-like behaviors in galaxies on the main sequence (Elbaz et al 2018), likely linked to the existence of transitional objects (Popping et al 2017;Barro et al 2017b;Gómez-Guijarro et al 2019;Puglisi et al 2019, and in prep. to limit the references to recent works based on submillimeter observations). Such transition might well imply an imminent increase of the SFR, driving the object in the realm of starbursts (e.g., Barro et al 2017b), or its cessation, bringing the system back onto or even below the main sequence (Gómez-Guijarro et al 2019;Puglisi et al 2019), with the CO properties potentially able to distinguish between these two scenarios.…”

Section: The Definition Of Starburstssupporting

confidence: 48%

“…We do detect starburst-like behaviors in galaxies on the main sequence (Elbaz et al 2018), likely linked to the existence of transitional objects (Popping et al 2017;Barro et al 2017b;Gómez-Guijarro et al 2019;Puglisi et al 2019, and in prep. to limit the references to recent works based on submillimeter observations). Such transition might well imply an imminent increase of the SFR, driving the object in the realm of starbursts (e.g., Barro et al 2017b), or its cessation, bringing the system back onto or even below the main sequence (Gómez-Guijarro et al 2019;Puglisi et al 2019), with the CO properties potentially able to distinguish between these two scenarios. Regardless of these transitional objects, a definition of starburst based on Σ SFR , rather than ∆MS, would naturally better account for the observed molecular gas excitation properties, dust temperatures and opacities, or SFE (see also Elbaz et al 2011;Rujopakarn et al 2011;Jiménez-Andrade et al 2018;Tacconi et al 2020).…”

Section: The Definition Of Starburstssupporting

confidence: 48%

“…The same definition of starbursts as galaxies deviating from the main sequence has been recently questioned with the advent of high spatial resolution measurements of their dust and gas emission. Compact galaxies with short depletion timescales typical of SBs are now routinely found on the MS, being possibly on their way to leave the sequence (Barro et al 2017a;Popping et al 2017;Elbaz et al 2018;Gómez-Guijarro et al 2019;Puglisi et al 2019;Jiménez-Andrade et al 2019); or galaxies moving within the MS scatter, due to mergers unable to efficiently boost the star formation (Fensch et al 2017) or owing to gravitational instabilities and gas radial redistribution (Tacchella et al 2016).…”

Section: Introductionmentioning

confidence: 99%

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CO emission in distant galaxies on and above the main sequence

Valentino

Daddi

Puglisi

et al. 2020

A&A

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We present the detection of multiple carbon monoxide CO line transitions with ALMA in a few tens of infrared-selected galaxies on and above the main sequence at z = 1.1−1.7. We reliably detected the emission of CO (5 − 4), CO (2 − 1), and CO (7 − 6)+[C I](3P2 − 3P1) in 50, 33, and 13 galaxies, respectively, and we complemented this information with available CO (4 − 3) and [C I](3P1 − 3P0) fluxes for part of the sample, and by modeling of the optical-to-millimeter spectral energy distribution. We retrieve a quasi-linear relation between LIR and CO (5 − 4) or CO (7 − 6) for main-sequence galaxies and starbursts, corroborating the hypothesis that these transitions can be used as star formation rate (SFR) tracers. We find the CO excitation to steadily increase as a function of the star formation efficiency, the mean intensity of the radiation field warming the dust (⟨U⟩), the surface density of SFR (ΣSFR), and, less distinctly, with the distance from the main sequence (ΔMS). This adds to the tentative evidence for higher excitation of the CO+[C I] spectral line energy distribution (SLED) of starburst galaxies relative to that for main-sequence objects, where the dust opacities play a minor role in shaping the high-J CO transitions in our sample. However, the distinction between the average SLED of upper main-sequence and starburst galaxies is blurred, driven by a wide variety of intrinsic shapes. Large velocity gradient radiative transfer modeling demonstrates the existence of a highly excited component that elevates the CO SLED of high-redshift main-sequence and starbursting galaxies above the typical values observed in the disk of the Milky Way. This excited component is dense and it encloses ∼50% of the total molecular gas mass in main-sequence objects. We interpret the observed trends involving the CO excitation as to be mainly determined by a combination of large SFRs and compact sizes, as a large ΣSFR is naturally connected with enhanced dense molecular gas fractions and higher dust and gas temperatures, due to increasing ultraviolet radiation fields, cosmic ray rates, as well as dust and gas coupling. We release the full data compilation and the ancillary information to the community.

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Section: The Definition Of Starburstssupporting

confidence: 48%

Section: The Definition Of Starburstssupporting

confidence: 48%

Section: Introductionmentioning

confidence: 99%

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CO emission in distant galaxies on and above the main sequence

Valentino

Daddi

Puglisi

et al. 2020

A&A

Self Cite

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“…Such high SFRs can partly disrupt clumps and molecular clouds (see Murray et al 2010) and may be subject to the Eddington limit for starbursts (e.g., Andrews & Thomson 2011;Simpson et al 2015). All in all, we expect limited, mildly obscured SFRs in the region between R Q and R rot , and a much stronger, obscured SFR in the innermost regions within R rot where most of the stellar mass is accumulated; therefore the SFRs probed by UV and far-IR data are expected to be spatially disconnected (e.g., Gomez-Guijarro et al 2018), with the UV morphology particularly knotty and irregular (e.g., Huertas-Company et al 2015). The above approximate analytical estimates of the SFRs, sizes R rot and velocity ratios (v/σ) rot are consistent with those measured via far-IR/sub-mm and CO line observations of z ∼ 1 − 2 star-forming galaxies (e.g., Barro et al 2016aBarro et al , 2017Hodge et al 2016;Tadaki et al 2017;Talia et al 2018).…”

Section: Compactionmentioning

confidence: 85%

The Dramatic Size and Kinematic Evolution of Massive Early-type Galaxies

Lapi

Pantoni

Zanisi

et al. 2018

ApJ

131

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We aim to provide a holistic view on the typical size and kinematic evolution of massive early-type galaxies (ETGs), that encompasses their high-z star-forming progenitors, their high-z quiescent counterparts, and their configurations in the local Universe. Our investigation covers the main processes playing a relevant role in the cosmic evolution of ETGs. Specifically, their early fast evolution comprises: biased collapse of the low angular momentum gaseous baryons located in the inner regions of the host dark matter halo; cooling, fragmentation, and infall of the gas down to the radius set by the centrifugal barrier; further rapid compaction via clump/gas migration toward the galaxy center, where strong heavily dust-enshrouded star-formation takes place and most of the stellar mass is accumulated; ejection of substantial gas amount from the inner regions by feedback processes, which causes a dramatic puffing up of the stellar component. In the late slow evolution, passive aging of stellar populations and mass additions by dry merger events occur. We describe these processes relying on prescriptions inspired by basic physical arguments and by numerical simulations, to derive new analytical estimates of the relevant sizes, timescales, and kinematic properties for individual galaxies along their evolution. Then we obtain quantitative results as a function of galaxy mass and redshift, and compare them to recent observational constraints on half-light size R e , on the ratio v/σ between rotation velocity and velocity dispersion (for gas and stars) and on the specific angular momentum j of the stellar component; we find good consistency with the available multi-band data in average values and dispersion, both for local ETGs and for their z ∼ 1 − 2 star-forming and quiescent progenitors. The outcomes of our analysis can provide hints to gauge sub-grid recipes implemented in simulations, to tune numerical experiments focused on specific processes, and to plan future multi-band, high-resolution observations on high-redshift star-forming and quiescent galaxies with next generation facilities.

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“…As previously suggested by Murphy et al (2017) and Thomson et al (2019), these differences may include frequencydependent cosmic-ray diffusion and/or may be due to the increasing thermal fraction at higher rest-frame radio frequencies, revealing time lags between the production of free-free and synchrotron emission in star-forming galaxies (e.g. Bressan et al 2002;Thomson et al 2014;Gómez-Guijarro et al 2019).…”

Section: The Radio Sizes Of Sfgs and Agn From Z = 1-3mentioning

confidence: 67%

The e-MERGE Survey (e-MERLIN Galaxy Evolution Survey): overview and survey description

Muxlow

Thomson

Radcliffe

et al. 2020

Monthly Notices of the Royal Astronomical Society

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We present an overview and description of the e-MERGE Survey (e-MERLIN Galaxy Evolution Survey) Data Release 1 (DR1), a large program of high-resolution 1.5-GHz radio observations of the GOODS-N field comprising ∼140 h of observations with enhanced-Multi-Element Remotely Linked Interferometer Network (e-MERLIN) and ∼40 h with the Very Large Array (VLA). We combine the long baselines of e-MERLIN (providing high angular resolution) with the relatively closely packed antennas of the VLA (providing excellent surface brightness sensitivity) to produce a deep 1.5-GHz radio survey with the sensitivity (${\sim}1.5\, \mu$ Jy beam−1), angular resolution (0.2–0.7 arcsec) and field-of-view (∼15 × 15 arcmin2) to detect and spatially resolve star-forming galaxies and active galactic nucleus (AGN) at $z$ ≳ 1. The goal of e-MERGE is to provide new constraints on the deep, sub-arcsecond radio sky which will be surveyed by SKA1-mid. In this initial publication, we discuss our data analysis techniques, including steps taken to model in-beam source variability over an ∼20-yr baseline and the development of new point spread function/primary beam models to seamlessly merge e-MERLIN and VLA data in the uv plane. We present early science results, including measurements of the luminosities and/or linear sizes of ∼500 galaxies selected at 1.5 GHz. In combination with deep Hubble Space Telescope observations, we measure a mean radio-to-optical size ratio of re-MERGE/rHST ∼ 1.02 ± 0.03, suggesting that in most high-redshift galaxies, the ∼GHz continuum emission traces the stellar light seen in optical imaging. This is the first in a series of papers that will explore the ∼kpc-scale radio properties of star-forming galaxies and AGN in the GOODS-N field observed by e-MERGE DR1.

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Compact Star-forming Galaxies as Old Starbursts Becoming Quiescent

Cited by 36 publications

References 98 publications

CO emission in distant galaxies on and above the main sequence

CO emission in distant galaxies on and above the main sequence

The Dramatic Size and Kinematic Evolution of Massive Early-type Galaxies

The e-MERGE Survey (e-MERLIN Galaxy Evolution Survey): overview and survey description

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