The Square Kilometre Array (SKA)

Illuminating the past 8 billion years of cold gas towards two gravitationally lensed quasars

Monthly Notices of the Royal Astronomical Society Oxford University Press 465:4 (2016) 4450-4467

Authors:

James Allison, VA Moss, J-P Macquart, SJ Curran, SW Duchesne, EK Mahony, EM Sadler, MT Whiting, KW Bannister, AP Chippendale, PG Edwards, L Harvey-Smith, Ian Heywood, BT Indermuehle, E Lenc, J Marvil, D McConnell, RJ Sault

Abstract:

Using the Boolardy Engineering Test Array of the Australian Square Kilometre Array Pathfinder (ASKAP BETA), we have carried out the first z = 0–1 survey for H I and OH absorption towards the gravitationally lensed quasars PKS B1830−211 and MG J0414+0534. Although we detected all previously reported intervening systems towards PKS B1830−211, in the case of MG J0414+0534, three systems were not found, indicating that the original identifications may have been confused with radio frequency interference. Given the sensitivity of our data, we find that our detection yield is consistent with the expected frequency of intervening H I systems estimated from previous surveys for 21-cm emission in nearby galaxies and z ∼ 3 damped Lyman α absorbers. We find spectral variability in the z = 0.886 face-on spiral galaxy towards PKS B1830−211 from observations undertaken with the Westerbork Synthesis Radio Telescope in 1997/1998 and ASKAP BETA in 2014/2015. The H I equivalent width varies by a few per cent over approximately yearly time-scales. This long-term spectral variability is correlated between the north-east and south-west images of the core, and with the total flux density of the source, implying that it is observationally coupled to intrinsic changes in the quasar. The absence of any detectable variability in the ratio of H I associated with the two core images is in stark contrast to the behaviour previously seen in the molecular lines. We therefore infer that coherent opaque H I structures in this galaxy are larger than the parsec-scale molecular clouds found at mm-wavelengths.

Galaxy and mass assembly: the 1.4 GHz SFR indicator, SFR–M* relation and predictions for ASKAP–GAMA

Monthly Notices of the Royal Astronomical Society Oxford University Press 466:2 (2016) 2312-2324

Authors:

Luke JM Davies, Minh T Huynh, Andrew M Hopkins, Nick Seymour, Simon P Driver, Aaron GR Robotham, Ivan K Baldry, Joss Bland-Hawthorn, Nathan Bourne, Malcolm N Bremer, Michael JI Brown, Sarah Brough, Michelle Cluver, Meiert W Grootes, Matthew Jarvis, Jonathan Loveday, Amanda Moffet, Matt Owers, Steven Phillipps, Elaine Sadler, Lingyu Wang, Stephen Wilkins, Angus Wright

Abstract:

We present a robust calibration of the 1.4 GHz radio continuum star formation rate (SFR) using a combination of the Galaxy And Mass Assembly (GAMA) survey and the Faint Images of the Radio Sky at Twenty-cm (FIRST) survey. We identify individually detected 1.4 GHz GAMA-FIRST sources and use a late-type, non-AGN, volume-limited sample from GAMA to produce stellar mass-selected samples. The latter are then combined to produce FIRST-stacked images. This extends the robust parametrisation of the 1.4 GHz-SFR relation to faint luminosities. For both the individually detected galaxies and our stacked samples, we compare 1.4 GHz luminosity to SFRs derived from GAMA to determine a new 1.4 GHz luminosity-to-SFR relation with well constrained slope and normalisation. For the first time, we produce the radio SFR-M⇤ relation over 2 decades in stellar mass, and find that our new calibration is robust, and produces a SFR-M⇤relation which is consistent with all other GAMA SFR methods. Finally, using our new 1.4 GHz luminosity-to-SFR calibration we make predictions for the number of star-forming GAMA sources which are likely to be detected in the upcoming ASKAP surveys, EMU and DINGO.

Simultaneous radio and X-ray observations of PSR B0611+22

Monthly Notices of the Royal Astronomical Society Oxford University Press 462:3 (2016) 2518-2526

Authors:

K Rajwade, A Seymour, DR Lorimer, Aris Karastergiou, M Serylak, MA McLaughlin, J-M Griessmeier

Abstract:

We report results from simultaneous radio and X-ray observations of PSR B0611+22 which is known to exhibit bursting in its single-pulse emission. The pulse phase of the bursts vary with radio frequency. The bursts are correlated in 327/150 MHz data sets while they are anti-correlated, with bursts at one frequency associated with normal emission at the other, in 820/150 MHz data sets. Also, the flux density of this pulsar is lower than expected at 327 MHz assuming a power law. We attribute this unusual behaviour to the pulsar itself rather than absorption by external astrophysical sources. Using this data set over an extensive frequency range, we show that the bursting phenomenon in this pulsar exhibits temporal variance over a span of few hours. We also show that the bursting is quasi-periodic over the observed band. The anti-correlation in the phase offset of the burst mode at different frequencies suggests that the mechanisms responsible for phase offset and flux enhancement have different dependencies on the frequency. We did not detect the pulsar with XMM-Newton and place a 99 per cent confidence upper limit on the X-ray efficiency of 10-5.

Gamma-ray Novae: Rare or Nearby?

(2016)

Authors:

Paul J Morris, Garret Cotter, Anthony M Brown, Paula M Chadwick

Flares, wind and nebulae: the 2015 December mini-outburst of V404 Cygni

Monthly Notices of the Royal Astronomical Society: Letters Oxford University Press (OUP) (2016) slw222

Authors:

T Mu noz-Darias, J Casares, D Mata Sánchez, RP Fender, M Armas Padilla, K Mooley, L Hardy, PA Charles, G Ponti, SE Motta, VS Dhillon, P Gandhi, F Jiménez Ibarra, T Butterley, S Carey, KJB Grainge, J Hickish, SP Littlefair, YC Perrott, N Razavi-Ghods, C Rumsey, AMM Scaife, PF Scott, DJ Titterington, RW Wilson