Galaxy formation and evolution

Integral field unit spectrograph for extremely large telescopes

Publications of the Astronomical Society of the Pacific 120:868 (2008) 634-643

Authors:

I Montilla, E Pécontal, J Devriendt, R Bacon

Abstract:

We have carried out a concept study for a wide-field monolithic integral field unit (IFU) spectrograph for extremely large telescopes (ELTs). We target in this paper the technological challenges that have to be faced in order to build such an instrument, focusing on the adaptive optics (AO) requirements, the image slicer technology, and the detectors status. We also address the main science drivers, together with the concept design and the expected performance applied to the European-ELT (E-ELT) case. A monolithic wide-field spectrograph provides a continuous field of view (FOV) separated by a field splitter in several subfields, each of them feeding a module featuring an image slicer, a collimator and a spectrograph. The use of image slicers provides 3D spectrographic images of the complete FOV, allowing for detection and study of sources without need of targeting them, a very useful property especially for the deep observation of faint high-redshift objects, whose density on the sky is expected to be quite high. In light of this discussion, we suggest the advantages of using shorter wavelengths and its implication in both the scientific program and the budget. © 2008. The Astronomical Society of the Pacific. All rights reserved.

Hunting for the Building Blocks of Galaxies like our own Milky Way with FORS

The Messenger 132 (2008) 41-45-41-45

Authors:

MG Haehnelt, M Rauch, A Bunker, G Becker, F Marleau, J Graham, S Cristiani, MJ Jarvis, C Lacey, S Morris, C Peroux, H Röttgering, T Theuns

Measuring the inclination and mass-to-light ratio of axisymmetric galaxies via anisotropic Jeans models of stellar kinematics

(2008)

A semi-empirical simulation of the extragalactic radio continuum sky for next generation radio telescopes

ArXiv 0805.3413 (2008)

Authors:

RJ Wilman, L Miller, MJ Jarvis, T Mauch, F Levrier, FB Abdalla, S Rawlings, H-R Kloeckner, D Obreschkow, D Olteanu, S Young

Abstract:

We have developed a semi-empirical simulation of the extragalactic radio continuum sky suitable for aiding the design of next generation radio interferometers such as the Square Kilometre Array (SKA). The emphasis is on modelling the large-scale cosmological distribution of radio sources rather than the internal details of individual galaxies. Here we provide a description of the simulation to accompany the online release of a catalogue of 320 million simulated radio sources. The simulation covers 20x20 deg^2 - a plausible upper limit to the instantaneous field of view attainable with future (e.g. SKA) aperture array technologies - out to redshift z=20, and down to flux density limits of 10 nJy at 151, 610 MHz, 1.4, 4.86 and 18 GHz. Five distinct source types are included: radio-quiet AGN, radio-loud AGN of the FRI and FRII structural classes, and star-forming galaxies, the latter split into populations of quiescent and starbursting galaxies. In our semi-empirical approach, the simulated sources are drawn from observed (or extrapolated) luminosity functions and grafted onto an underlying dark matter density field with biases which reflect their measured large-scale clustering. A numerical Press-Schechter-style filtering of the density field is used to identify and populate clusters of galaxies. Radio source structures are built from point source and elliptical sub-components, and for FRI and FRII sources an orientation-based unification and beaming model is used to partition flux between the core and extended lobes and hotspots. The simulation output can be post-processed to achieve more complete agreement with observational data in the years ahead, with the aim of using these 'idealised skies' in telescope simulators to optimise the design of the SKA itself (abridged).

MUSE: A second-generation integral-field spectrograph for the VLT

ESO Astrophysics Symposia 2008 (2008) 325-336

Authors:

RM Mcdermid, R Bacon, S Bauer, P Boehm, D Boudon, S Brau-Nogué, P Caillier, L Capoani, CM Carollo, N Champavert, T Contini, E Daguisé, 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, JL Lizon, M Loupias, A Manescau, C Monstein, H Nicklas, L Parès, L Pasquini, A Pécontal-rousset, E Pécontal, R Pello, C Petit, JP Picat, E Popow, A Quirrenbach, R Reiss, E Renault, M Roth, J Schaye, G Soucail, M Steinmetz, S Stroebele, R Stuik, P Weilbacher, L Wisotzki, H Wozniak, PT de Zeeuw

Abstract:

The Multi Unit Spectroscopic Explorer (MUSE) is a second-generation instrument in development for the Very Large Telescope (VLT) of the European Southern Observatory (ESO), due to begin operation in 2011/12. MUSE will be an extremely powerful integral-field spectrograph fed by a new multiple-laser adaptive optics system on the VLT. In its usual operating mode, MUSE will, in a single observation, produce a 3-dimensional data cube consisting of 90,000 R 3000 spectra, each covering a full spectral octave (480-930 nm), and fully sampling a contiguous 1×1 arcmin2 field with 0.2×0.2 arcsec2 apertures. A high-resolution mode will increase the spatial sampling to 0.025 arcsec per pixel. MUSE is built around a novel arrangement of 24 identical spectrographs (each comparable to a 1st generation VLT instrument), which are fed by a set of 24 precision image slicers. MUSE is designed for stability, with only 2 modes, and virtually no moving parts, allowing very long exposures to be accumulated. Together with high throughput, this ensures that MUSE will have extreme sensitivity for observing faint objects. We overview the technical and scientific aspects of MUSE, highlighting the key challenges for dealing with the unprecedented quantity and complexity of the data, and the integration with the VLT adaptive optics facility (AOF) - a key development on the path to extremely large telescopes (ELTs). © 2008 Springer-Verlag Berlin Heidelberg.