Combined Co and Dust Scaling Relations of Depletion Time and Molecular Gas Fractions With Cosmic Time, Specific Star-Formation Rate, and Stellar Mass

Genzel, R.; Tacconi, L. J.; Lutz, D.; Saintonge, A.; Berta, S.; Magnelli, B.; Combes, F.; García‐Burillo, S.; Neri, R.; Bolatto, Alberto D.; Contini, T.; Lilly, S. J.; Boissier, J.; Boone, F.; Bouché, Nicolas; Bournaud, F.; Burkert, Andreas; Carollo, M.; Colina, L.; Cooper, M. C.; Cox, P.; Feruglio, C.; Schreiber, N. M. Förster; Freundlich, Jonathan; Graciá-Carpio, J.; Juneau, Stéphanie; Kovač, K.; Lippa, M.; Naab, Thorsten; Salomé, P.; Renzini, A.; Sternberg, A.; Walter, Fabian; Weiner, Benjamin J.; Weiß, A.; Wuyts, Stijn

doi:10.1088/0004-637x/800/1/20

Cited by 572 publications

(843 citation statements)

References 179 publications

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“…While studies of nearby star-forming galaxies suggest that the surface density of ongoing star formation is most closely tied to the dense H2 gas (Bigiel et al , 2011Leroy et al 2008), observed molecular depletion timescales are much shorter than the inferred quenching timescales. For relatively massive galaxies (M 10 10 M ), spanning a broad range of redshift, current observations point towards molecular depletion timescales of roughly 1 − 2 Gyr (Bigiel et al 2011;Leroy et al 2013;Saintonge et al 2011;Tacconi et al 2010Tacconi et al , 2013Genzel et al 2010Genzel et al , 2015. Moreover, recent work targeting larger samples of lower-mass galaxies conclude that the molecular depletion timescale decreases with decreasing stellar mass, such that infalling satellites at 10 9 M should, on average, exhaust their molecular reservoirs in less than 1 Gyr (Saintonge et al 2011;Boselli et al 2014).…”

Section: Discussionmentioning

confidence: 95%

Taking care of business in a flash : constraining the time-scale for low-mass satellite quenching with ELVIS

Fillingham

Cooper

Wheeler

et al. 2015

Mon. Not. R. Astron. Soc.

134

190

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The vast majority of dwarf satellites orbiting the Milky Way and M31 are quenched, while comparable galaxies in the field are gas-rich and star-forming. Assuming that this dichotomy is driven by environmental quenching, we use the ELVIS suite of N -body simulations to constrain the characteristic timescale upon which satellites must quench following infall into the virial volumes of their hosts. The high satellite quenched fraction observed in the Local Group demands an extremely short quenching timescale (∼ 2 Gyr) for dwarf satellites in the mass range M ∼ 10 6 − 10 8 M . This quenching timescale is significantly shorter than that required to explain the quenched fraction of more massive satellites (∼ 8 Gyr), both in the Local Group and in more massive host halos, suggesting a dramatic change in the dominant satellite quenching mechanism at M 10 8 M . Combining our work with the results of complementary analyses in the literature, we conclude that the suppression of star formation in massive satellites (M ∼ 10 8 − 10 11 M ) is broadly consistent with being driven by starvation, such that the satellite quenching timescale corresponds to the cold gas depletion time. Below a critical stellar mass scale of ∼ 10 8 M , however, the required quenching times are much shorter than the expected cold gas depletion times. Instead, quenching must act on a timescale comparable to the dynamical time of the host halo. We posit that ram-pressure stripping can naturally explain this behavior, with the critical mass (of M ∼ 10 8 M ) corresponding to halos with gravitational restoring forces that are too weak to overcome the drag force encountered when moving through an extended, hot circumgalactic medium.

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Section: Discussionmentioning

confidence: 95%

Taking care of business in a flash : constraining the time-scale for low-mass satellite quenching with ELVIS

Fillingham

Cooper

Wheeler

et al. 2015

Mon. Not. R. Astron. Soc.

134

190

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“…with redshift (see also Riechers et al 2010;Casey et al 2011;Geach et al 2011;Aravena et al 2012Aravena et al , 2016Magnelli et al 2012;Bothwell et al 2013;Saintonge et al 2013;Tacconi et al 2013;Chapman et al 2015a;Genzel et al 2015). …”

Section: H2mentioning

confidence: 95%

The Alma Spectroscopic Survey in the Hubble Ultra Deep Field: Molecular Gas Reservoirs in High-Redshift Galaxies

Decarli

Walter

Aravena

et al. 2016

ApJ

Self Cite

104

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We study the molecular gas properties of high-z galaxies observed in the ALMA Spectroscopic Survey (ASPECS) that targets a ∼ 1 arcmin 2 region in the Hubble Ultra Deep Field (UDF), a blind survey of CO emission (tracing molecular gas) in the 3 mm and 1 mm bands. Of a total of 1302 galaxies in the field, 56 have spectroscopic redshifts and correspondingly well-defined physical properties. Among these, 11 have infrared luminosities L IR > 10 11 L , i.e. a detection in CO emission was expected. Out these, 7 are detected at various significance in CO, and 4 are undetected in CO emission. In the CO-detected sources, we find CO excitation conditions that are lower than typically found in starburst/SMG/QSO environments. We use the CO luminosities (including limits for non-detections)

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“…Thus the stellar mass of the progenitor is M * = 10 10.25 M . Using table 4 in Genzel et al (2015), and assuming that the total gas mass is 1.4 times the molecular gas mass, we obtain Mgas ≈ 10 10.43 M . This value is consistent with gas mass observations in ULIRGs with similar properties (e.g., Solomon et al 1997).…”

Section: Quenching Timescalesmentioning

confidence: 99%

“…Genzel et al (2015) combine multiple observations of CO emission and Herschel far-IR dust measurements of over 500 star forming galaxies, and derive molecular gas masses using different methods. Their sample spans the redshift range 0-3, stellar masses of M * = 10 10−11.5 M , and the relative specific star formation rate (sSFR; see definition there) of log(sSFR/sSFR(ms, z, M * )) = −1.5 − 2.…”

Section: Quenching Timescalesmentioning

confidence: 99%

Evidence of ongoing AGN-driven feedback in a quiescent post-starburst E+A galaxy

Baron

Netzer

Poznanski

et al. 2017

Monthly Notices of the Royal Astronomical Society

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Post starburst E+A galaxies are thought to have experienced a significant starburst that was quenched abruptly. Their disturbed, bulge-dominated morphologies suggest that they are merger remnants. We present ESI/Keck observations of SDSS J132401.63+454620.6, a post starburst galaxy at redshift z = 0.125, with a starburst that started 400 Myr ago, and other properties, like star formation rate (SFR) consistent with what is measured in ultra luminous infrared galaxies (ULRIGs). The galaxy shows both zero velocity narrow lines, and blueshifted broader Balmer and forbidden emission lines (FWHM=1350 ± 240 km s −1 ). The narrow component is consistent with LINER-like emission, and the broader component with Seyfert-like emission, both photoionized by an active galactic nucleus (AGN) whose properties we measure and model. The velocity dispersion of the broad component exceeds the escape velocity, and we estimate the mass outflow rate to be in the range 4-120 M /yr. This is the first reported case of AGN-driven outflows, traced by ionized gas, in post starburst E+A galaxies. We show, by ways of a simple model, that the observed AGN-driven winds can consistently evolve a ULIRG into the observed galaxy. Our findings reinforce the evolutionary scenario where the more massive ULIRGs are quenched by negative AGN feedback, evolve first to post starburst galaxies, and later become typical red and dead ellipticals.

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Combined Co and Dust Scaling Relations of Depletion Time and Molecular Gas Fractions With Cosmic Time, Specific Star-Formation Rate, and Stellar Mass

Cited by 572 publications

References 179 publications

Taking care of business in a flash : constraining the time-scale for low-mass satellite quenching with ELVIS

Taking care of business in a flash : constraining the time-scale for low-mass satellite quenching with ELVIS

The Alma Spectroscopic Survey in the Hubble Ultra Deep Field: Molecular Gas Reservoirs in High-Redshift Galaxies

Evidence of ongoing AGN-driven feedback in a quiescent post-starburst E+A galaxy

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