The Sloan Lens Acs Survey. X. Stellar, Dynamical, and Total Mass Correlations of Massive Early-Type Galaxies

Auger, Matthew W.; Treu, Tommaso; Bolton, A.; Gavazzi, R.; Koopmans, L. V. E.; Marshall, Phil; Moustakas, Leonidas A.; Burles, Scott

doi:10.1088/0004-637x/724/1/511

Cited by 509 publications

(882 citation statements)

References 98 publications

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“…Such low-mass stars are difficult to observe directly. However, the best estimates currently available, including those based on direct spectral tracers of lowmass stars, favor bottom-heavy IMFs consistent with Salpeter or even steeper slopes (Auger et al 2010;Conroy et al 2013;Sonnenfeld et al 2017;, which are also consistent with our results. These IMFs should scale with galaxy mass, but not with redshift (Sonnenfeld et al 2017); this is consistent with mainly passively evolving stellar populations since redshifts z = 1-2.…”

Section: Evidence For a Bottom-heavy Imfsupporting

confidence: 91%

“…The mass profiles of massive galaxies at low redshift suggest that dark matter contributes at most 10 % to the total mass out to 6-7 kpc (Auger et al 2010;Conroy et al 2013) and probably less in our source at z = 1.5, owing to gradual dark-matter assembly (Macciò et al 2008). The non-detection of the dust continuum with ALMA (C17) also rules out masses of cold molecular and atomic gas above on the order of 10 9 M (1 % of M lens ), for a simple scaling with the range of gas-to-dust ratios between 40 and 100, as measured by C15.…”

Section: Evidence For a Bottom-heavy Imfmentioning

confidence: 99%

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Planck’s dusty GEMS

Cañameras

Nesvadba

Kneißl

et al. 2017

A&A

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We study the properties of the foreground galaxy of the Ruby, the brightest gravitationally lensed high-redshift galaxy on the sub-millimeter sky as probed by the Planck satellite, and part of our sample of Planck's Dusty GEMS. The Ruby consists of an Einstein ring of 1.4 diameter at z = 3.005 observed with ALMA at 0.1 resolution, centered on a faint, red, massive lensing galaxy seen with HST/WFC3, which itself has an exceptionally high redshift, z = 1.525 ± 0.001, as confirmed with VLT/X-Shooter spectroscopy. Here we focus on the properties of the lens and the lensing model obtained with LENSTOOL. The rest-frame optical morphology of this system is strongly dominated by the lens, while the Ruby itself is highly obscured, and contributes less than 10 % to the photometry out to the K band. The foreground galaxy has a lensing mass of (3.70 ± 0.35) × 10 11 M . Magnification factors are between 7 and 38 for individual clumps forming two image families along the Einstein ring. We present a decomposition of the foreground and background sources in the WFC3 images, and stellar population synthesis modeling with a range of star-formation histories for Chabrier and Salpeter initial mass functions (IMFs). Only the stellar mass range obtained with the latter agrees well with the lensing mass. This is consistent with the bottom-heavy IMFs of massive high-redshift galaxies expected from detailed studies of the stellar masses and mass profiles of their low-redshift descendants, and from models of turbulent gas fragmentation. This may be the first direct constraint on the IMF in a lens at z = 1.5, which is not a cluster central galaxy.

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Section: Evidence For a Bottom-heavy Imfsupporting

confidence: 91%

Section: Evidence For a Bottom-heavy Imfmentioning

confidence: 99%

Planck’s dusty GEMS

Cañameras

Nesvadba

Kneißl

et al. 2017

A&A

Self Cite

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“…The latter point is not a significant concern here, since the highest redshift source has an impact parameter with respect to the z = 0.609 source that is more than three times larger than the Einstein radius θ E s1 . Similarly, the power-law description for the central total mass density distribution is motivated by the absence of any correlation between the power-law indices and radii of strong lenses (e.g., Koopmans et al 2006Koopmans et al , 2009Auger et al 2010), as well as the power-law behaviour of the total mass distribution over a large range of scales from the ensemble weak lensing mass profile of lenses (Gavazzi et al 2007) and mass profiles of massive X-ray-bright galaxies (Humphrey & Buote 2010). Furthermore, Suyu et al (2013) have explicitly modelled one time delay gravitational lens, RX J1131-1231, with both a power-law and a stars-plus-dark matter model and find no significant difference in the cosmographic inference between the two models when stellar kinematics are included in the modelling; a similar analysis for J0946 is under way.…”

Section: Discussionmentioning

confidence: 99%

Cosmological constraints from the double source plane lens SDSSJ0946+1006

Collett

Auger

2014

Monthly Notices of the Royal Astronomical Society

115

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We present constraints on the equation of state of dark energy, w, and the total matter density, Ω M , derived from the double-source-plane strong lens SDSSJ0946+1006, the first cosmological measurement with a galaxy-scale doublesource-plane lens. By modelling the primary lens with an elliptical power-law mass distribution, and including perturbative lensing by the first source, we are able to constrain the cosmological scaling factor in this system to be β −1 = 1.404 ± 0.016, which implies Ω M = 0.33 +0.33 −0.26 for a flat ΛCDM cosmology. Combining with a CMB prior from Planck, we find w = −1.17 +0.20 −0.21 assuming a flat wCDM cosmology. This inference shifts the posterior by 1σ and improves the precision by 30 per cent with respect to Planck alone, and demonstrates the utility of combining simple, galaxy-scale multiple-source-plane lenses with other cosmological probes to improve precision and test for residual systematic biases.

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“…• For a galaxy with a proxy velocity dispersion of 266 km/s and an effective radius of 6.17 kpc, average for the Auger et al (2010) sample, the calibrated fractional stellar surface mass density peaks at a value of 1.10 at 0.074r e , as shown in Figure 3. At 1.5r e , the typical Einstein radius for our lens systems, the stellar mass fraction is 0.25.…”

Section: Salient Features Of the Analysismentioning

confidence: 96%

Stellar masses calibrated with micro-lensed quasars

Schechter¹,

Blackburne²,

Pooley³

et al. 2014

Proc. IAU

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Abstract. We measure the stellar mass surface densities of early type galaxies by observing the micro-lensing of macro-lensed quasars caused by individual stars, including stellar remnants, brown dwarfs and red dwarfs too faint to produce photometric or spectroscopic signatures. Our method measures the graininess of the gravitational potential, in contrast to methods that decompose a smooth total gravitational potential into two smooth components, one stellar and one dark. We find the median likelihood value for the calibration factor F by which Salpeter stellar masses (with a low mass cutoff of 0.1M ) must be multiplied is 1.23, with a one sigma confidence range of 0.77 < F < 2.10.

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The Sloan Lens Acs Survey. X. Stellar, Dynamical, and Total Mass Correlations of Massive Early-Type Galaxies

Cited by 509 publications

References 98 publications

Planck’s dusty GEMS

Planck’s dusty GEMS

Cosmological constraints from the double source plane lens SDSSJ0946+1006

Stellar masses calibrated with micro-lensed quasars

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