Hintze Centre for Astrophysical Surveys

The faint radio source population at 15.7 GHz - II. Multi-wavelength properties

Monthly Notices Of The Royal Astronomical Society Oxford University Press 453:4 (2015) 4244-4263

Authors:

Imogen Whittam, Julia Riley, Dave Green, Matthew Jarvis, Mattia Vaccari

Abstract:

A complete, flux density limited sample of 96 faint ($> 0.5$ mJy) radio sources is selected from the 10C survey at 15.7 GHz in the Lockman Hole. We have matched this sample to a range of multi-wavelength catalogues, including SERVS, SWIRE, UKIDSS and optical data; multi-wavelength counterparts are found for 80 of the 96 sources and spectroscopic redshifts are available for 24 sources. Photometric reshifts are estimated for the sources with multi-wavelength data available; the median redshift of the sample is 0.91 with an interquartile range of 0.84. Radio-to-optical ratios show that at least 94 per cent of the sample are radio loud, indicating that the 10C sample is dominated by radio galaxies. This is in contrast to samples selected at lower frequencies, where radio-quiet AGN and starforming galaxies are present in significant numbers at these flux density levels. All six radio-quiet sources have rising radio spectra, suggesting that they are dominated by AGN emission. These results confirm the conclusions of Paper I that the faint, flat-spectrum sources which are found to dominate the 10C sample below $\sim 1$ mJy are the cores of radio galaxies. The properties of the 10C sample are compared to the SKADS Simulated Skies; a population of low-redshift starforming galaxies predicted by the simulation is not found in the observed sample.

A supernova distance to the anchor galaxy NGC 4258⋆

Astronomy & Astrophysics EDP Sciences 580 (2015) l15

Authors:

J Polshaw, R Kotak, KC Chambers, SJ Smartt, S Taubenberger, M Kromer, EEE Gall, W Hillebrandt, M Huber, KW Smith, RJ Wainscoat

DIVISION J COMMISSION 28: GALAXIES

Proceedings of the International Astronomical Union Cambridge University Press (CUP) 11:T29A (2015) 525-530

Authors:

John S Gallagher, Roger L Davies, Stéphane Courteau, Avishai Dekel, Marijn Franx, Chanda J Jog, Sardha Jogee, Naomasa Nakai, Monica Rubio, Linda Tacconi, Elena Terlevich

The Type IIb SN 2011dh: Two years of observations and modelling of the lightcurves ⋆⋆⋆

Astronomy & Astrophysics EDP Sciences 580 (2015) a142

Authors:

M Ergon, A Jerkstrand, J Sollerman, N Elias-Rosa, C Fransson, M Fraser, A Pastorello, R Kotak, S Taubenberger, L Tomasella, S Valenti, S Benetti, G Helou, MM Kasliwal, J Maund, SJ Smartt, J Spyromilio

Counting quasar–radio source pairs to derive the millijansky radio luminosity function and clustering strength to z = 3.5

Monthly Notices of the Royal Astronomical Society Oxford University Press 452:3 (2015) 2692-2699

Authors:

S Fine, T Shanks, R Johnston, Matthew Jarvis, T Mauch

Abstract:

We apply a cross-correlation technique to infer the S > 3 mJy radio luminosity function (RLF) from the NRAO VLA Sky Survey (NVSS) to z ∼ 3.5. We measure Σ the over density of radio sources around spectroscopically confirmed quasars. Σ is related to the space density of radio sources at the distance of the quasars and the clustering strength between the two samples, hence knowledge of one constrains the other. Under simple assumptions we find Φ ∝ (1 + z)3.7 ± 0.7 out to z ∼ 2. Above this redshift the evolution slows and we constrain the evolution exponent to <1.01 (2σ). This behaviour is almost identical to that found by previous authors for the bright end of the RLF potentially indicating that we are looking at the same population. This suggests that the NVSS is dominated by a single population; most likely radio sources associated with high-excitation cold-mode accretion. Inversely, by adopting a previously modelled RLF we can constrain the clustering of high-redshift radio sources and find a clustering strength consistent with r0 = 15.0 ± 2.5 Mpc up to z ∼ 3.5. This is inconsistent with quasars at low redshift and some measurements of the clustering of bright FR II sources. This behaviour is more consistent with the clustering of lower luminosity radio galaxies in the local Universe. Our results indicate that the high-excitation systems dominating our sample are hosted in the most massive galaxies at all redshifts sampled.