Your search keyword '"Léon V E Koopmans"' showing total 3 results

1. Building the Largest Spectroscopic Sample of Ultracompact Massive Galaxies with the Kilo Degree Survey.

Author

Diana Scognamiglio, Crescenzo Tortora, Marilena Spavone, Chiara Spiniello, Nicola R. Napolitano, Giuseppe D’Ago, Francesco La Barbera, Fedor Getman, Nivya Roy, Maria Angela Raj, Mario Radovich, Massimo Brescia, Stefano Cavuoti, Léon V. E. Koopmans, Konrad H. Kuijken, Giuseppe Longo, and Carlo E. Petrillo

Subjects

*GALAXIES, *STELLAR mass, *DEFINITIONS, *CENSUS

Abstract

Ultracompact massive galaxies (ucmgs), i.e., galaxies with stellar masses and effective radii , are very rare systems, in particular at low and intermediate redshifts. Their origin as well as their number density across cosmic time are still under scrutiny, especially because of the paucity of spectroscopically confirmed samples. We have started a systematic census of ucmg candidates within the ESO Kilo Degree Survey, together with a large spectroscopic follow-up campaign to build the largest possible sample of confirmed ucmgs. This is the third paper of the series and the second based on the spectroscopic follow-up program. Here, we present photometrical and structural parameters of 33 new candidates at redshifts and confirm 19 of them as ucmgs, based on their nominal spectroscopically inferred and . This corresponds to a success rate of , nicely consistent with our previous findings. The addition of these 19 newly confirmed objects allows us to fully assess the systematics on the system selection—and to finally reduce the number density uncertainties. Moreover, putting together the results from our current and past observational campaigns and some literature data, we build the largest sample of ucmgs ever collected, comprising 92 spectroscopically confirmed objects at . This number raises to 116, allowing for a 3σ tolerance on the and thresholds for the ucmg definition. For all these galaxies, we have estimated the velocity dispersion values at the effective radii, which have been used to derive a preliminary mass–velocity dispersion correlation. [ABSTRACT FROM AUTHOR]

Published

2020

2. The Sloan Lens ACS Survey. XIII. Discovery of 40 New Galaxy-scale Strong Lenses.

Author

Yiping Shu, Joel R. Brownstein, Adam S. Bolton, Léon V. E. Koopmans, Tommaso Treu, Antonio D. Montero-Dorta, Matthew W. Auger, Oliver Czoske, Raphaël Gavazzi, Philip J. Marshall, and Leonidas A. Moustakas

Subjects

*DARK matter, *GALACTIC evolution, *GRAVITATIONAL lenses, *ASTRONOMICAL observations, *INTERSTELLAR medium

Abstract

We present the full sample of 118 galaxy-scale strong-lens candidates in the Sloan Lens ACS (SLACS) Survey for the Masses (S4TM) Survey, which are spectroscopically selected from the final data release of the Sloan Digital Sky Survey. Follow-up Hubble Space Telescope (HST) imaging observations confirm that 40 candidates are definite strong lenses with multiple lensed images. The foreground-lens galaxies are found to be early-type galaxies (ETGs) at redshifts 0.06–0.44, and background sources are emission-line galaxies at redshifts 0.22–1.29. As an extension of the SLACS Survey, the S4TM Survey is the first attempt to preferentially search for strong-lens systems with relatively lower lens masses than those in the pre-existing strong-lens samples. By fitting HST data with a singular isothermal ellipsoid model, we find that the total projected mass within the Einstein radius of the S4TM strong-lens sample ranges from 3 × 1010M⊙ to 2 × 1011M⊙. In Shu et al., we have derived the total stellar mass of the S4TM lenses to be 5 × 1010M⊙ to 1 × 1012M⊙. Both the total enclosed mass and stellar mass of the S4TM lenses are on average almost a factor of 2 smaller than those of the SLACS lenses, which also represent the typical mass scales of the current strong-lens samples. The extended mass coverage provided by the S4TM sample can enable a direct test, with the aid of strong lensing, for transitions in scaling relations, kinematic properties, mass structure, and dark-matter content trends of ETGs at intermediate-mass scales as noted in previous studies. [ABSTRACT FROM AUTHOR]

Published

2017

3. THE SLOAN LENS ACS SURVEY. XII. EXTENDING STRONG LENSING TO LOWER MASSES.

Author

Yiping Shu, Adam S. Bolton, Joel R. Brownstein, Antonio D. Montero-Dorta, Léon V. E. Koopmans, Tommaso Treu, Raphaël Gavazzi, Matthew W. Auger, Oliver Czoske, Philip J. Marshall, and Leonidas A. Moustakas

Subjects

*GALAXIES, *STELLAR activity, *SOLAR activity, *DARK matter, *IMAGE processing

Abstract

We present observational results from a new Hubble Space Telescope (HST) Snapshot program to extend the methods of the Sloan Lens ACS (SLACS) Survey to lower lens-galaxy masses. We discover 40 new galaxy-scale strong lenses, which we supplement with 58 previously discovered SLACS lenses. In addition, we determine the posterior PDFs of the Einstein radius for 33 galaxies (18 new and 15 from legacy SLACS data) based on single lensed images. We find a less-than-unity slope of 0.64 ± 0.06 for the − relation, which corresponds to a 6σ evidence that the total mass–density profile of early-type galaxies varies systematically in the sense of being shallower at higher lens-galaxy velocity dispersions. The trend is only significant when single-image systems are considered, highlighting the importance of including both “lenses” and “nonlenses” for an unbiased treatment of the lens population when extending to lower mass ranges. By scaling simple stellar-population models to the HST I-band data, we identify a strong trend of increasing dark-matter fraction at higher velocity dispersions, which can be alternatively interpreted as a trend in the stellar initial mass function (IMF) normalization. Consistent with previous findings and the suggestion of a nonuniversal IMF, we find that a Salpeter IMF is ruled out for galaxies with velocity dispersion less than 180 km s−1. Considered together, our mass-profile and dark-matter fraction trends with increasing galaxy mass could both be explained by an increasing relative contribution on kiloparsec scales from a dark-matter halo with a spatial profile more extended than that of the stellar component. [ABSTRACT FROM AUTHOR]

Published

2015