Galaxy formation and evolution

The Stellar Mass Density at z~6 from Spitzer Imaging of i-drop Galaxies

(2006)

Authors:

Laurence Eyles, Andrew Bunker, Richard Ellis, Mark Lacy, Elizabeth Stanway, Daniel Stark, Kuenley Chiu

Sinfoni integral field spectroscopy of z ∼ 2 UV-selected galaxies: Rotation curves and dynamical evolution

Astrophysical Journal 645:2 I (2006) 1062-1075

Authors:

NM Förster Schreiber, R Genzei, MD Lehnert, N Bouché, A Verma, DK Erb, AE Shapley, CC Steidel, R Davies, D Lutz, N Nesvadba, LJ Tacconi, F Eisenhauer, R Abuter, A Gilbert, S Gillessen, A Sternberg

Abstract:

We present ∼0″5 resolution near-infrared integral field spectroscopy of the Hα line emission of 14 z ∼ 2 UV-selected BM/BX galaxies, obtained with SINFONI at the ESO Very Large Telescope. The average Hα half-light radius is r1/2 ≈4 h70^-1 kpc, and line emission is detected over ≳20 h70^-1 kpc in several sources. In nine galaxies, we detect spatially resolved velocity gradients, from 40 to 410 km s^-1 over ∼10 h70 ^-1 kpc. The kinematics of the larger systems are generally consistent with orbital motions. Four galaxies are well described by rotating clumpy disks, and we extracted rotation curves out to radii ≳10 h 70^-1 kpc. One or two galaxies exhibit signatures more consistent with mergers. Analyzing all 14 galaxies in the framework of rotating disks, we infer mean inclination- and beam-corrected maximum circular velocities of vc ∼ 180 ± 90 km s^-1 and dynamical masses from ∼0.5 to 25 × 10¹⁰ h70^-1 M ⊙ within r1/2- The specific angular momenta of our BM/BX galaxies are similar to those of local late-type galaxies. Moreover, the specific angular momenta of their baryons are comparable to those of their dark matter halos. Extrapolating from the average vc at 10 h 70^-1 kpc, the virial mass of the typical halo of a galaxy in our sample is 10^11.7±0.5 h70^-1 M ⊙. Kinematic modeling of the three best cases implies a ratio of vc to local velocity dispersion vc/σ ∼ 2-4 and, accordingly, a large geometric thickness. We argue that this suggests a mass accretion (alternatively, gas exhaustion) timescale of ∼500 Myr. We also argue that if our BM/BX galaxies were initially gas-rich, their clumpy disks would subsequently lose their angular momentum and form compact bulges on a timescale of ∼1 Gyr. © 2006. The American Astronomical Socieity. All rights reserved.

The Masses of Nuclear Black Holes in Luminous Elliptical Galaxies and Implications for the Space Density of the Most Massive Black Holes

(2006)

Authors:

Tod R Lauer, SM Faber, Douglas Richstone, Karl Gebhardt, Scott Tremaine, Marc Postman, Alan Dressler, MC Aller, Alexei V Filippenko, Richard Green, Luis C Ho, John Kormendy, John Magorrian, Jason Pinkney

Probing unexplored territories with MUSE: a second generation instrument for the VLT

ArXiv astro-ph/0606329 (2006)

Authors:

R Bacon, S Bauer, P Boehm, D Boudon, S Brau-Nogue, P Caillier, L Capoani, CM Carollo, N Champavert, T Contini, E Daguise, D Dalle, B Delabre, J Devriendt, S Dreizler, J Dubois, M Dupieux, JP Dupin, E Emsellem, P Ferruit, M Franx, G Gallou, J Gerssen, B Guiderdoni, T Hahn, D Hofmann, A Jarno, A Kelz, C Koehler, W Kollatschny, J Kosmalski, F Laurent, SJ Lilly, J Lizon, M Loupias, S Lynn, A Manescau, RM McDermid, C Monstein, H Nicklas, L Pares, L Pasquini, A Pecontal-Rousset, E Pecontal, R Pello, C Petit, J-P Picat, E Popow, A Quirrenbach, R Reiss, E Renault, M Roth, J Schaye, G Soucail, M Steinmetz, S Stroebele, R Stuik, P Weilbacher, H Wozniak, PT de Zeeuw

Abstract:

The Multi Unit Spectroscopic Explorer (MUSE) is a second-generation VLT panoramic integral-field spectrograph under preliminary design study. MUSE has a field of 1x1 arcmin**2 sampled at 0.2x0.2 arcsec**2 and is assisted by the VLT ground layer adaptive optics ESO facility using four laser guide stars. The simultaneous spectral range is 465-930 nm, at a resolution of R~3000. MUSE couples the discovery potential of a large imaging device to the measuring capabilities of a high-quality spectrograph, while taking advantage of the increased spatial resolution provided by adaptive optics. This makes MUSE a unique and tremendously powerful instrument for discovering and characterizing objects that lie beyond the reach of even the deepest imaging surveys. MUSE has also a high spatial resolution mode with 7.5x7.5 arcsec**2 field of view sampled at 25 milli-arcsec. In this mode MUSE should be able to obtain diffraction limited data-cubes in the 600-930 nm wavelength range. Although the MUSE design has been optimized for the study of galaxy formation and evolution, it has a wide range of possible applications; e.g. monitoring of outer planets atmosphere, environment of young stellar objects, super massive black holes and active nuclei in nearby galaxies or massive spectroscopic surveys of stellar fields in the Milky Way and nearby galaxies.

Probing unexplored territories with MUSE: a second generation instrument for the VLT

(2006)

Authors:

R Bacon, S Bauer, P Boehm, D Boudon, S Brau-Nogue, P Caillier, L Capoani, CM Carollo, N Champavert, T Contini, E Daguise, D Dalle, B Delabre, J Devriendt, S Dreizler, J Dubois, M Dupieux, JP Dupin, E Emsellem, P Ferruit, M Franx, G Gallou, J Gerssen, B Guiderdoni, T Hahn, D Hofmann, A Jarno, A Kelz, C Koehler, W Kollatschny, J Kosmalski, F Laurent, SJ Lilly, J Lizon, M Loupias, S Lynn, A Manescau, RM McDermid, C Monstein, H Nicklas, L Pares, L Pasquini, A Pecontal-Rousset, E Pecontal, R Pello, C Petit, J-P Picat, E Popow, A Quirrenbach, R Reiss, E Renault, M Roth, J Schaye, G Soucail, M Steinmetz, S Stroebele, R Stuik, P Weilbacher, H Wozniak, PT de Zeeuw