Extremely Large Telescope

Extraplanar gas and magnetic fields in the cluster spiral galaxy NGC 4569

Proceedings of the International Astronomical Union Cambridge University Press (CUP) 2:S237 (2006) 470-470

Authors:

S Ryś, KT Chyży, M Weżgowiec, M Ehle, R Beck

Triaxial orbit-based model of NGC 4365

Proceedings of the International Astronomical Union Cambridge University Press (CUP) 2:S238 (2006) 331-332

Authors:

Remco CE van den Bosch, Glenn van de Ven, Michele Cappellari, P Tim de Zeeuw

Dark matter in the central regions of early type galaxies

EAS Publications Series 20 (2006) 127-130

Authors:

M Cappellari, R Bacon, M Bureau, MC Damen, RL Davies, PT De Zeeuw, E Emsellem, J Falcon-Barroso, D Krajnović, H Kuntschner, RM McDermid, RF Peletier, M Sarzi, RCE Van Den Bosch, G Van De Ven

Abstract:

We investigate the well-known correlations between the dynamical rnass-to-light ratio M/L and other global observables of elliptical (E) arid lenticular (S0) galaxies. We construct two-integral Jeans and three-integral Schwarzschild dynamical models for a sample of 25 E/S0 galaxies with SAURON integral-field stellar kinematics to about one effective (half-light) radius Re. The comparison of the dynamical M/L with the (M/L)pop inferred from the analysis of the stellar population, indicates that dark matter in early-type galaxies contributes ∼30% of the total mass inside one Re, in agreement with previous studies, with significant variations from galaxy to galaxy. Our results suggest a variation in M/L at constant (M/L)pop, which seems to be linked to the galaxy dynamics. We speculate that fast rotating galaxies have lower dark matter fractions than the slow rotating and generally more massive ones. © EAS, EDP Sciences 2006.

A Time Delay for the Largest Gravitationally Lensed Quasar: SDSS J1004+4112

(2006)

Authors:

J Fohlmeister, CS Kochanek, EE Falco, J Wambsganss, N Morgan, CW Morgan, EO Ofek, D Maoz, CR Keeton, JC Barentine, G Dalton, J Dembicky, W Ketzeback, R McMillan, CS Peters

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 1011.7±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.