Cosmology

Herschel-atlas: A binary HyLIRG pinpointing a cluster of starbursting protoellipticals

Astrophysical Journal 772:2 (2013)

Authors:

RJ Ivison, AM Swinbank, I Smail, AI Harris, RS Bussmann, A Cooray, P Cox, H Fu, A Kovács, M Krips, D Narayanan, M Negrello, R Neri, J Peñarrubia, J Richard, DA Riechers, K Rowlands, JG Staguhn, TA Targett, S Amber, AJ Baker, N Bourne, F Bertoldi, M Bremer, JA Calanog, DL Clements, H Dannerbauer, A Dariush, G De Zotti, L Dunne, SA Eales, D Farrah, S Fleuren, A Franceschini, JE Geach, RD George, JC Helly, R Hopwood, E Ibar, MJ Jarvis, JP Kneib, S Maddox, A Omont, D Scott, S Serjeant, MWL Smith, MA Thompson, E Valiante, I Valtchanov, J Vieira, P Van Der Werf

Abstract:

Panchromatic observations of the best candidate hyperluminous infrared galaxies from the widest Herschel extragalactic imaging survey have led to the discovery of at least four intrinsically luminous z = 2.41 galaxies across an ≈100 kpc region - a cluster of starbursting protoellipticals. Via subarcsecond interferometric imaging we have measured accurate gas and star formation surface densities. The two brightest galaxies span ∼3 kpc FWHM in submillimeter/radio continuum and CO J = 4-3, and double that in CO J = 1-0. The broad CO line is due partly to the multitude of constituent galaxies and partly to large rotational velocities in two counter-rotating gas disks - a scenario predicted to lead to the most intense starbursts, which will therefore come in pairs. The disks have M dyn of several × 1011 M o, and gas fractions of ∼40%. Velocity dispersions are modest so the disks are unstable, potentially on scales commensurate with their radii: these galaxies are undergoing extreme bursts of star formation, not confined to their nuclei, at close to the Eddington limit. Their specific star formation rates place them ≳ 5 × above the main sequence, which supposedly comprises large gas disks like these. Their high star formation efficiencies are difficult to reconcile with a simple volumetric star formation law. N-body and dark matter simulations suggest that this system is the progenitor of a B(inary)-type ≈1014.6- o cluster. © 2013. The American Astronomical Society. All rights reserved.

The preferentially magnified active nucleus in IRAS F10214+4724 - III. VLBI observations of the radio core

ArXiv 1307.6566 (2013)

Authors:

RP Deane, S Rawlings, MA Garrett, I Heywood, MJ Jarvis, H-R Klöckner, PJ Marshall, JP McKean

Abstract:

We report 1.7 GHz Very Long Baseline Interferometry (VLBI) observations of IRAS F10214+4724, a lensed z=2.3 obscured quasar with prodigious star formation. We detect what we argue to be the obscured active nucleus with an effective angular resolution of < 50 pc at z = 2.3 . The S_{1.7} = 210 micro-Jy (9-\sigma) detection of this unresolved source is located within the HST rest-frame ultraviolet/optical arc, however, >~100 mas northward of the arc centre of curvature. This leads to a source plane inversion that places the European VLBI Network detection to within milli-arcseconds of the modelled cusp caustic, resulting in a very large magnification (\mu ~70), over an order of magnitude larger than the CO (1-0) derived magnification of a spatially resolved JVLA map, using the same lens model. We estimate the quasar bolometric luminosity from a number of independent techniques and with our X-ray modelling find evidence that the AGN may be close to Compton-thick, with an intrinsic bolometric luminosity log(L_{bol,QSO} / L_sun) = 11.34 +- 0.27 dex. We make the first black hole mass estimate of IRAS F10214+4724 and find log(M_{BH}/M_sun) = 8.36 +- 0.56 which suggests a low black hole accretion rate (\lambda = \dot{M} / \dot{M}_{Edd} ~ 3\pm^7_2 percent). We find evidence for a M_{BH}/M_{spheroid} ratio that is 1-2 orders of magnitude larger than that of submillimetre galaxies (SMGs) at z~2. At face value, this suggests IRAS F10214+4724 has undergone a different evolutionary path compared to SMGs at the same epoch. A primary result of this work is the demonstration that emission regions of differing size and position can undergo significantly different magnification boosts (> 1 dex) and therefore distort our view of high-redshift, gravitationally lensed galaxies.

Evolution of star formation in the UKIDSS Ultra Deep Survey field – I. Luminosity functions and cosmic star formation rate out to z = 1.6

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 433:1 (2013) 796-811

Authors:

Alyssa B Drake, Chris Simpson, Chris A Collins, Phil A James, Ivan K Baldry, Masami Ouchi, Matt J Jarvis, David G Bonfield, Yoshiaki Ono, Philip N Best, Gavin B Dalton, James S Dunlop, Ross J McLure, Daniel JB Smith

A 325-MHz GMRT survey of the Herschel-ATLAS/GAMA fields

ArXiv 1307.459 (2013)

Authors:

T Mauch, H-R Klöckner, S Rawlings, MJ Jarvis, MJ Hardcastle, D Obreschkow, DJ Saikia, MA Thompson

Abstract:

We describe a 325-MHz survey, undertaken with the Giant Metrewave Radio Telescope (GMRT), which covers a large part of the three equatorial fields at 9, 12 and 14.5 h of right ascension from the Herschel-Astrophysical Terahertz Large Area Survey (H-ATLAS) in the area also covered by the Galaxy And Mass Assembly survey (GAMA). The full dataset, after some observed pointings were removed during the data reduction process, comprises 212 GMRT pointings covering ~90 deg^2 of sky. We have imaged and catalogued the data using a pipeline that automates the process of flagging, calibration, self-calibration and source detection for each of the survey pointings. The resulting images have resolutions of between 14 and 24 arcsec and minimum rms noise (away from bright sources) of ~1 mJy/beam, and the catalogue contains 5263 sources brighter than 5 sigma. We investigate the spectral indices of GMRT sources which are also detected at 1.4 GHz and find them to agree broadly with previously published results; there is no evidence for any flattening of the radio spectral index below S_1.4=10 mJy. This work adds to the large amount of available optical and infrared data in the H-ATLAS equatorial fields and will facilitate further study of the low-frequency radio properties of star formation and AGN activity in galaxies out to z~1.

Herschel-ATLAS/GAMA: The environmental density of far-infrared bright galaxies at z ≤ = 0.5

Monthly Notices of the Royal Astronomical Society 433:1 (2013) 771-786

Authors:

CS Burton, MJ Jarvis, DJB Smith, DG Bonfield, MJ Hardcastle, JA Stevens, N Bourne, M Baes, S Brough, A Cava, A Cooray, A Dariush, G De Zotti, L Dunne, S Eales, R Hopwood, E Ibar, RJ Ivison, J Liske, J Loveday, SJ Maddox, M Negrello, MWL Smith, E Valiante

Abstract:

We compare the environmental and star formation properties of far-infrared detected and non-far-infrared detected galaxies out to z ~ 0.5. Using optical spectroscopy and photometryfrom the Galaxy And Mass Assembly (GAMA) and Sloan Digital Sky Survey, with farin frared observations from the Herschel Astrophysical Terahertz Large Area Survey (ATLAS)Science Demonstration Phase, we apply the technique of Voronoi tessellations to analyse the environmental densities of individual galaxies. Applying statistical analyses to colour, r-band magnitude and redshift-matched samples, we show that there is a significant differenceat the 3.5σ level between the normalized environmental densities of these two populations. This is such that infrared emission (a tracer of star formation activity) favours underden seregions compared to those inhabited by exclusively optically observed galaxies selected to beof the same r-band magnitude, colour and redshift. Thus, more highly star-forming galaxiesare found to reside in the most underdense environments, confirming previous studies thathave proposed such a correlation. However, the degeneracy between redshift and far-infraredluminosity in our flux-density-limited sample means that we are unable to make a strongerstatement in this respect. We then apply our method to synthetic light cones generated fromsemi-analytic models, finding that over the whole redshift distribution the same correlations between star formation rate and environmental density are found. © 2013 The Authors Published by Oxford University Press on behalf of the Royal Astronomical Society.