Galaxy formation and evolution

Natural guide-star processing for wide-field laser-assisted AO systems

Adaptive Optics Systems V Society of Photo-optical Instrumentation Engineers (2016)

Authors:

Carlos M Correia, Benoit Neichel, Jean-Marc Conan, Cyril Petit, Jean-Francois Sauvage, Thierry Fusco, Joel DR Vernet, Niranjan Thatte

Abstract:

Sky-coverage in laser-assisted AO observations largely depends on the system's capability to guide on the faintest natural guide-stars possible. Here we give an up-to-date status of our natural guide-star processing tailored to the European-ELT's visible and near-infrared (0.47 to 2.45 μm) integral field spectrograph — Harmoni.
We tour the processing of both the isoplanatic and anisoplanatic tilt modes using the spatio-angular approach whereby the wavefront is estimated directly in the pupil plane avoiding a cumbersome explicit layered estimation on the 35-layer profiles we're currently using.
Taking the case of Harmoni, we cover the choice of wave-front sensors, the number and field location of guide-stars, the optimised algorithms to beat down angular anisoplanatism and the performance obtained with different temporal controllers under split high-order/low-order tomography or joint tomography. We consider both atmospheric and far greater telescope wind buffeting disturbances. In addition we provide the sky-coverage estimates thus obtained.

Preparation of AO-related observations and post-processing recipes for E-ELT HARMONI-SCAO

Proceedings of SPIE--the International Society for Optical Engineering SPIE, the international society for optics and photonics 9909 (2016) 990978-990978-10

Authors:

Noah Schwartz, Jean-François Sauvage, Carlos Correia, Benoît Neichel, Léonardo Blanco, Thierry Fusco, Arlette Pécontal-Rousset, Aurélien Jarno, Laure Piqueras, Kjetil Dohlen, Kacem El Hadi, Niranjan Thatte, Ian Bryson, Fraser Clarke, Hermine Schnetler

The adaptive optics modes for HARMONI: from Classical to Laser Assisted Tomographic AO

Proceedings of SPIE--the International Society for Optical Engineering SPIE, the international society for optics and photonics 9909 (2016) 990909-990909-15

Authors:

B Neichel, T Fusco, J-F Sauvage, C Correia, K Dohlen, K El-Hadi, L Blanco, N Schwartz, F Clarke, NA Thatte, M Tecza, J Paufique, J Vernet, M Le Louarn, P Hammersley, J-L Gach, S Pascale, P Vola, C Petit, J-M Conan, A Carlotti, C Vérinaud, H Schnetler, I Bryson, T Morris, R Myers, E Hugot, AM Gallie, David M Henry

GAMA/WiggleZ: The 1.4GHz radio luminosity functions of high- and low-excitation radio galaxies and their redshift evolution to z=0.75

Monthly Notices of the Royal Astronomical Society Oxford University Press 460:1 (2016) 2-17

Authors:

Michael B Pracy, John HY Ching, Elaine M Sadler, Scott M Croom, IK Baldry, Joss Bland-Hawthorn, S Brough, MJI Brown, Warwick Couch, Tamara M Davis, Michael J Drinkwater, Matthew Jarvis, Ben Jelliffe, Russell J Jurek, J Loveday, KA Pimbblet, M Prescott, Emily Wisnioski, David Woods

Abstract:

We present radio active galactic nuclei (AGN) luminosity functions over the redshift range 0.005 < z < 0.75. The sample from which the luminosity functions are constructed is an optical spectroscopic survey of radio galaxies, identified from matched Faint Images of the Radio Sky at Twenty-cm survey (FIRST) sources and Sloan Digital Sky Survey images. The radio AGN are separated into low-excitation radio galaxies (LERGs) and high-excitation radio galaxies (HERGs) using the optical spectra. We derive radio luminosity functions for LERGs and HERGs separately in the three redshift bins (0.005 < z < 0.3, 0.3 < z < 0.5 and 0.5 < z < 0.75). The radio luminosity functions can be well described by a double power law. Assuming this double power-law shape the LERG population displays little or no evolution over this redshift range evolving as ∼(1+z)0.06+0.17−0.18 assuming pure density evolution or ∼(1+z)0.46+0.22−0.24 assuming pure luminosity evolution. In contrast, the HERG population evolves more rapidly, best fitted by ∼(1+z)2.93+0.46−0.47 assuming a double power-law shape and pure density evolution. If a pure luminosity model is assumed, the best-fitting HERG evolution is parametrized by ∼(1+z)7.41+0.79−1.33 . The characteristic break in the radio luminosity function occurs at a significantly higher power (≳1 dex) for the HERG population in comparison to the LERGs. This is consistent with the two populations representing fundamentally different accretion modes.

LOFAR/H-ATLAS: a deep low-frequency survey of the Herschel-ATLAS North Galactic Pole field

Monthly Notices of the Royal Astronomical Society Oxford University Press 462:2 (2016) 1910-1936

Authors:

Martin J Hardcastle, Gulay Gürkan, Reinout J van Weeren, Wendy L Williams, Philip N Best, Francesco de Gasperin, David A Rafferty, Sean C Read, José Sabater Montes, Tim W Shimwell, Daniel JB Smith, Cyril Tasse, Nathan Bourne, Marissa Brienza, Marcus Brüggen, Gianfranco Brunetti, Krzysztof T Chyży, John Conway, Loretta Dunne, Steve A Eales, Steve J Maddox, Matthew Jarvis, Elizabeth K Mahony, Raffaella Morganti, Isabella Prandoni, Huub JA Röttgering, Elisabetta Valiante, Glenn J White

Abstract:

We present Low-Frequency Array (LOFAR) High-Band Array observations of the Herschel-ATLAS North Galactic Pole survey area. The survey we have carried out, consisting of four pointings covering around 142 deg2 of sky in the frequency range 126–173 MHz, does not provide uniform noise coverage but otherwise is representative of the quality of data to be expected in the planned LOFAR wide-area surveys, and has been reduced using recently developed ‘facet calibration’ methods at a resolution approaching the full resolution of the data sets (∼10 × 6 arcsec) and an rms off-source noise that ranges from 100 μJy beam−1 in the centre of the best fields to around 2 mJy beam−1 at the furthest extent of our imaging. We describe the imaging, cataloguing and source identification processes, and present some initial science results based on a 5σ source catalogue. These include (i) an initial look at the radio/far-infrared correlation at 150 MHz, showing that many Herschel sources are not yet detected by LOFAR; (ii) number counts at 150 MHz, including, for the first time, observational constraints on the numbers of star-forming galaxies; (iii) the 150-MHz luminosity functions for active and star-forming galaxies, which agree well with determinations at higher frequencies at low redshift, and show strong redshift evolution of the star-forming population; and (iv) some discussion of the implications of our observations for studies of radio galaxy life cycles.