Galaxy Luminosity Functions to<i>z</i>∼1 from DEEP2 and COMBO‐17: Implications for Red Galaxy Formation

Faber, S. M.; Willmer, Christopher N. A.; Wolf, Christian; Koo, David C.; Weiner, Benjamin J.; Newman, J. A.; Im, Myungshin; Coil, Alison L.; Conroy, Charlie; Cooper, Michael C.; Davis, Marc; Finkbeiner, Douglas P.; Gerke, Brian F.; Gebhardt, Karl; Groth, Edward J.; Guhathakurta, Puragra; Harker, Justin; Kaiser, Nick; Kassin, Susan; Kleinheinrich, M.; Konidaris, Nicholas P.; Krön, Richard G.; Lin, Lihwai; Luppino, Gerard A.; Madgwick, Darren; Meisenheimer, K.; Noeske, K. G.; Phillips, Andrew C.; Sarajedini, Vicki L.; Schiavon, Ricardo P.; Simard, Luc; Szalay, Alexander S.; Vogt, Nicole P.; Yan, Renbin

doi:10.1086/519294

Cited by 982 publications

(1,129 citation statements)

References 220 publications

(392 reference statements)

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“…Through conservation of the angular momentum, dissipation transforms the gaseous structure into a star-forming disk (Hopkins et al, 2009). Owning that the gas fraction in galaxy increases with redshift (as suggested by Faber, 2007;Lotz et al, 2010), this last point sheds light on the formation history of low-redshift spiral galaxies.…”

Section: Gas Dynamicsmentioning

confidence: 85%

Tides in Colliding Galaxies

Duc

Renaud

2013

Lecture Notes in Physics

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Long tails and streams of stars are the most noticeable upshots of galaxy collisions. Their origin as gravitational, tidal, disturbances has however been recognized only less than fifty years ago and more than ten years after their first observations. This Review describes how the idea of galactic tides emerged, in particular thanks to the advances in numerical simulations, from the first ones that included tens of particles to the most sophisticated ones with tens of millions of them and state-of-the-art hydrodynamical prescriptions. Theoretical aspects pertaining to the formation of tidal tails are then presented. The third part of the review turns to observations and underlines the need for collecting deep multi-wavelength data to tackle the variety of physical processes exhibited by collisional debris. Tidal tails are not just stellar structures, but turn out to contain all the components usually found in galactic disks, in particular atomic / molecular gas and dust. They host star-forming complexes and are able to form star-clusters or even second-generation dwarf galaxies. The final part of the review discusses what tidal tails can tell us (or not) about the structure and content of present-day galaxies, including their dark components, and explains how tidal tails may be used to probe the past evolution of galaxies and their mass assembly history. On-going deep wide-field surveys disclose many new lowsurface brightness structures in the nearby Universe, offering great opportunities for attempting galactic archeology with tidal tails.

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Section: Gas Dynamicsmentioning

confidence: 85%

Tides in Colliding Galaxies

Duc

Renaud

2013

Lecture Notes in Physics

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“…The associated heating rate per co-moving volume would likewise have been larger then, while the total amount of stellar mass in elliptical galaxies was smaller (Bell et al 2004;Faber et al 2007). Thus, this form of feedback would have more important (more ergs per gram) than at present.…”

Section: Co-evolution Of Galaxies and Black Holesmentioning

confidence: 99%

The Co-Evolution of Galaxies and Black Holes: Current Status and Future Prospects

Heckman

2009

Proc. IAU

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Abstract. I begin by summarizing the evidence that there is a close relationship between the evolution of galaxies and supermassive black holes. They evidently share a common fuel source, and feedback from the black hole may be needed to suppress over-cooling in massive galaxies.I then review what we know about the co-evolution of galaxies and black holes in the modern universe (z < 1). We now have a good documentation of which black holes are growing (the lower mass ones), where they are growing (in the less massive early-type galaxies), and how this growth is related in a statistical sense to star formation in the central region of the galaxy. The opportunity in the next decade will be to use the new observatories to undertake ambitious programs of 3-D imaging spectroscopy of the stars and gas in order to understand the actual astrophysical processes that produce the demographics we observe. At high redshift (z > 2), the most massive black holes and the progenitors of the most massive galaxies are forming. Here, we currently have a tantalizing but fragmented view of their co-evolution. In the next decade, the huge increase in sensitivity and discovery power of our observatories will enable us to analyze the large, complete samples we need to achieve robust and clear results.

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“…In color-magnitude space, the red galaxies populate a tight relation (often called the red sequence), while the distribution of blue galaxies is more scattered (sometimes referred to as the blue cloud). While the red and blue populations comprise approximately equal portions of the cosmic stellar mass budget at z ∼ 1, galaxies on the red sequence dominate today, following a growth in stellar mass within the red population of roughly a factor of 2 over the past 7 Gyr (Bell et al 2004;Bundy et al 2006;Faber et al 2007;Brown et al 2007). Despite uncertainty regarding the particular physical process(es) at play, the suppression (or quenching) of star formation in blue galaxies, thereby making them red, is one of the principal drivers of this dramatic growth in the number density of quiescent systems at late cosmic time.…”

Section: Introductionmentioning

confidence: 99%

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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Galaxy Luminosity Functions toz∼1 from DEEP2 and COMBO‐17: Implications for Red Galaxy Formation

Cited by 982 publications

References 220 publications

Tides in Colliding Galaxies

Tides in Colliding Galaxies

The Co-Evolution of Galaxies and Black Holes: Current Status and Future Prospects

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

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