The Square Kilometre Array (SKA)

Towards a unified model for black hole X-ray binary jets

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 355:4 (2004) 1105-1118

Authors:

RP Fender, TM Belloni, E Gallo

Using SKA to observe relativistic jets from X-ray binary systems

New Astronomy Reviews Elsevier 48:11-12 (2004) 1399-1412

Upper Limits on Central Black Hole Masses of Globular Clusters from Radio Emission and a Possible Black Hole Detection in the Ursa Minor Dwarf Galaxy

(2004)

Authors:

Thomas J Maccarone, Robert P Fender, Anastasios K Tzioumis

Near-infrared K-band imaging of a sample of ultra-steep-spectrum radio sources selected at 74 MHz

\mnras 355 (2004) 20-30-20-30

Authors:

MJ Jarvis, MJ Cruz, AS Cohen, HJA Röttgering, NE Kassim

The radio source population at high frequency: Follow-up of the 15-GHz 9C survey

Monthly Notices of the Royal Astronomical Society 354:2 (2004) 485-521

Authors:

RC Bolton, G Cotter, GG Pooley, JM Riley, EM Waldram, CJ Chandler, BS Mason, TJ Pearson, ACS Readhead

Abstract:

We have carried out extensive radio and optical follow-up of 176 sources from the 15-GHz 9th Cambridge survey. Optical identifications have been found for 155 of the radio sources; optical images are given with radio maps overlaid. The continuum radio spectrum of each source spanning the frequency range 1. 4-43 GHz is also given. Two flux-limited samples are defined, one containing 124 sources complete to 25 mJy and one of 70 sources complete to 60 mJy. Between one-fifth and one-quarter of sources from these flux-limited samples display convex radio spectra, rising between 1.4 and 4.8 GHz. These rising-spectrum sources make up a much larger fraction of the radio source population at this high selection frequency than in lower frequency surveys. We find that by using non-simultaneous survey flux density measurements at 1.4 and 15 GHz to remove steep-spectrum objects, the efficiency of selecting objects with spectra rising between 1.4 and 4.8 GHz (as seen in simultaneous measurements) can be raised to 49 per cent without compromising the completeness of the rising-spectrum sample.