The inferred evolution of the cold gas properties of CANDELS galaxies at 0.5 &lt;<i>z</i>&lt; 3.0

Popping, Gergö; Caputi, K.; Trager, S. C.; Somerville, Rachel S.; Dekel, Avishai; Kassin, Susan; Kocevski, Dale D.; Koekemoer, Anton M.; Faber, S. M.; Ferguson, Henry C.; Galametz, A.; Grogin, Norman A.; Guo, Y.; Lu, Yu; Wel, Arjen van der; Weiner, Benjamin J.

doi:10.1093/mnras/stv2136

Cited by 45 publications

(53 citation statements)

References 106 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…G1's star-formation efficiency, defined as SFR/MHI, is relatively high, SFE=3.5 × 10 −10 yr −1 , for the bulk of starforming galaxies (Popping et al 2015). On the other hand, the cool gas fraction, defined as MHI/(MHI + M * ), falls just below average for z = 0.7: fgas ≈ 0.4 (e.g., Popping et al 2015).…”

Section: Damped Lyα Systemsmentioning

confidence: 99%

Slicing the cool circumgalactic medium along the major axis of a star-forming galaxy at z = 0.7

López

Tejos

Barrientos

et al. 2019

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

We present spatially-resolved echelle spectroscopy of an intervening Mg ii-Fe ii-Mg i absorption-line system detected at z abs = 0.73379 toward the giant gravitational arc PSZ1 G311. 65-18.48. The absorbing gas is associated to an inclined disk-like starforming galaxy, whose major axis is aligned with the two arc-segments reported here. We probe in absorption the galaxy's extended disk continuously, at ≈ 3 kpc sampling, from its inner region out to 15× the optical radius. We detect strong (W 2796 0 > 0.3Å) coherent absorption along 13 independent positions at impact parameters D = 0-29 kpc on one side of the galaxy, and no absorption at D = 28-57 kpc on the opposite side (all de-lensed distances at z abs ). We show that: (1) the gas distribution is anisotropic; (2) W 2796 0 , W 2600 0 , W 2852 0 , and the ratio W 2600 0 /W 2796 0 , all anti-correlate with D; (3) the W 2796 0-D relation is not cuspy and exhibits significantly less scatter than the quasar-absorber statistics; (4) the absorbing gas is co-rotating with the galaxy out to D 20 kpc, resembling a 'flat' rotation curve, but at D 20 kpc velocities decline below the expectations from a 3D disk-model extrapolated from the nebular [O ii] emission. These signatures constitute unambiguous evidence for rotating extra-planar diffuse gas, possibly also undergoing enriched accretion at its edge. Arguably, we are witnessing some of the long-sought processes of the baryon cycle in a single distant galaxy expected to be representative of such phenomena.

show abstract

Section: Damped Lyα Systemsmentioning

confidence: 99%

Slicing the cool circumgalactic medium along the major axis of a star-forming galaxy at z = 0.7

López

Tejos

Barrientos

et al. 2019

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

show abstract

“…For instance, Papovich et al (2015) inferred that while the gas fraction in M31-type galaxies has decreased to lower than 20% at z ∼ 1.5, it is still high for MW-sized galaxies at ∼40%, consistent with the fraction estimated here. See also Popping et al (2015). Snaith et al (2014;2015; orange curve, left axis), together with the gas fraction evolution in the model (thin black curve and right axis).…”

Section: Chemical Evolution Model and Derived Sfhmentioning

confidence: 99%

When the Milky Way turned off the lights: APOGEE provides evidence of star formation quenching in our Galaxy

Haywood

Lehnert

Matteo

et al. 2016

A&A

149

174

View full text Add to dashboard Cite

Quenching, the cessation of star formation, is one of the most significant events in the life cycle of galaxies. While quenching is generally thought to be linked to their central regions, the mechanism responsible for it is not known and may not even be unique. We show here the first evidence that the Milky Way experienced a generalised quenching of its star formation at the end of its thick-disk formation ∼9 Gyr ago. The fossil record imprinted on the elemental abundances of stars studied in the solar vicinity and as part of the APOGEE survey (APOGEE is part of the Sloan Digital Sky Survey III) reveals indeed that in less than ∼2 Gyr (from 10 to 8 Gyr ago) the star formation rate in our Galaxy dropped by an order of magnitude. Because of the tight correlation that exists between age and α abundance, the general cessation of the star formation activity reflects in the dearth of stars along the inner-disk sequence in the [Fe/H]-[α/Fe] plane. Before this phase, which lasted about 1.5 Gyr, the Milky Way was actively forming stars. Afterwards, the star formation resumed at a much lower level to form the thin disk. These events observed in our Galaxy are very well matched by the latest observation of MW-type progenitors at high redshifts. In late-type galaxies, the quenching mechanism is believed to be related to a long and secular exhaustion of gas. Our results show that in the Milky Way, the shut-down occurred on a much shorter timescale, while the chemical continuity between the stellar populations formed before and after the quenching indicates that it is not the exhaustion of the gas that was responsible for the cessation of the star formation. While quenching is generally associated with spheroids in the literature, our results show that it also occurs in galaxies like the Milky Way, where the classical bulge is thought to be small or non-existent, possibly when they are undergoing a morphological transition from thick to thin disks. Given the demographics of late-type galaxies in the local Universe, in which classical bulges are rare, we suggest further that this may hold true generally in galaxies with mass lower than or approximately of M * , where quenching could directly be a consequence of thick-disk formation, while quenching may be related to development of spheroids in higher mass galaxies. We emphasize that the quenching phase in the Milky Way could be contemporaneous with, and related to, the formation of the bar, at the end of the thick-disk phase. We sketch a scenario on how a strong bar may inhibit star formation.

show abstract

“…The corrected PHIBSS sample is seen now to lie closer to the Santini et al (2014) relation but it still lies somewhat below and with a scatter slightly larger than the mass slice would predict. In order to obtain a better evaluation of how the relation based on f mol−gas compares to that of the total gas mass relation, we also include CANDELS galaxies from Popping et al (2015) for which total SFRs are also known. The molecular gas mass for the CANDELS galaxies has not been measured, rather it has been inferred from a suite of optical data and the model presented in Popping et al (2015).…”

Section: The Sfr Molecular Gas Fraction and Stellar Mass Relationsmentioning

confidence: 99%

“…In order to obtain a better evaluation of how the relation based on f mol−gas compares to that of the total gas mass relation, we also include CANDELS galaxies from Popping et al (2015) for which total SFRs are also known. The molecular gas mass for the CANDELS galaxies has not been measured, rather it has been inferred from a suite of optical data and the model presented in Popping et al (2015). It is seen that for f mol−gas < 0.2 the CANDELS sample follows the Santini et al (2014) relation well, whereas it for larger f mol−gas connects perfectly with the PHIBSS sample.…”

Section: The Sfr Molecular Gas Fraction and Stellar Mass Relationsmentioning

confidence: 99%

ALMA + VLT observations of a damped Lyman-α absorbing galaxy: massive, wide CO emission, gas-rich but with very low SFR

Møller

Christensen

Zwaan

et al. 2017

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

We are undertaking an ALMA survey of molecular gas in galaxies selected for their strong HI absorption, so-called DLA/sub-DLA galaxies. Here we report CO(2-1) detection from a DLA galaxy at z = 0.716. We also present optical and near-infrared spectra of the galaxy revealing [OII], Hα and [NII] emission lines shifted by ∼ 170 km s −1 relative to the DLA, and providing an oxygen abundance 3.2 times solar, similar to the absorption metallicity. We report low unobscured SFR∼ 1 M ⊙ yr −1 given the large reservoir of molecular gas, and also modest obscured SFR= 4.5 . Surprisingly, this HI absorption-selected galaxy has no equivalent objects in CO surveys of flux-selected samples. The galaxy falls off current scaling relations for the SFR to molecular gas mass and CO Tully-Fisher relation. Detailed comparison of kinematical components of the absorbing, ionized and molecular gas, combined with their spatial distribution, suggests that part of the CO gas is both kinematically and spatially de-coupled from the main galaxy. It is thus possible that a major star burst in the past could explain the wide CO profile as well as the low SFR. Support for this also comes from the SED favouring an instantaneous burst of age ≈ 0.5 Gyr. Our survey will establish whether flux-selected surveys of molecular gas are missing a key stage in the evolution of galaxies and their conversion of gas to stars.

show abstract

The inferred evolution of the cold gas properties of CANDELS galaxies at 0.5 <z< 3.0

Cited by 45 publications

References 106 publications

Slicing the cool circumgalactic medium along the major axis of a star-forming galaxy at z = 0.7

Slicing the cool circumgalactic medium along the major axis of a star-forming galaxy at z = 0.7

When the Milky Way turned off the lights: APOGEE provides evidence of star formation quenching in our Galaxy

ALMA + VLT observations of a damped Lyman-α absorbing galaxy: massive, wide CO emission, gas-rich but with very low SFR

Contact Info

Product

Resources

About