The Square Kilometre Array (SKA)

The peculiar mass-loss history of SN 2014C as revealed through AMI radio observations

(2016)

Authors:

GE Anderson, A Horesh, KP Mooley, AP Rushton, RP Fender, TD Staley, MK Argo, RJ Beswick, PJ Hancock, MA Perez-Torres, YC Perrott, RM Plotkin, ML Pretorius, C Rumsey, DJ Titterington

The peculiar mass-loss history of SN 2014C as revealed through AMI radio observations

Monthly Notices of the Royal Astronomical Society Oxford University Press 466:3 (2016) 3648-3662

Authors:

GE Anderson, A Horesh, Kunal P Mooley, Anthony P Rushton, Robert P Fender, Timothy D Staley, MK Argo, RJ Beswick, PJ Hancock, MA Pérez-Torres, YC Perrott, RM Plotkin, ML Pretorius, C Rumsey, DJ Titterington

Abstract:

We present a radio light curve of supernova (SN) 2014C taken with the Arcminute Microkelvin Imager (AMI) Large Array at 15.7 GHz. Optical observations presented by Milisavljevic et al. demonstrated that SN 2014C metamorphosed from a stripped-envelope Type Ib SN into a strongly interacting Type IIn SN within 1 yr. The AMI light curve clearly shows two distinct radio peaks, the second being a factor of 4 times more luminous than the first peak. This double bump morphology indicates two distinct phases of mass-loss from the progenitor star with the transition between density regimes occurring at 100-200 d. This reinforces the interpretation that SN 2014C exploded in a low-density region before encountering a dense hydrogen-rich shell of circumstellar material that was likely ejected by the progenitor prior to the explosion. The AMI flux measurements of the first light-curve bump are the only reported observations taken within ~50 to ~125 d post-explosion, before the blast-wave encountered the hydrogen shell. Simplistic synchrotron self-absorption and free-free absorption modelling suggest that some physical properties of SN 2014C are consistent with the properties of other Type Ibc and IIn SNe. However, our single frequency data does not allow us to distinguish between these two models, which implies that they are likely too simplistic to describe the complex environment surrounding this event. Lastly, we present the precise radio location of SN 2014C obtained with the electronic Multi-Element Remotely Linked Interferometer Network, which will be useful for future very long baseline interferometry observations of the SN.

Disc–jet quenching of the galactic black hole Swift J1753.5−0127

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 463:1 (2016) 628-634

Authors:

AP Rushton, AW Shaw, RP Fender, D Altamirano, P Gandhi, P Uttley, PA Charles, M Kolehmainen, GE Anderson, C Rumsey, DJ Titterington

Rapid Radio Flaring during an Anomalous Outburst of SS Cyg

(2016)

Authors:

KP Mooley, JCA Miller-Jones, RP Fender, GR Sivakoff, C Rumsey, Y Perrott, D Titterington, K Grainge, TD Russell, SH Carey, J Hickish, N Razavi-Ghods, A Scaife, P Scott, EO Waagen

HIPSR: A digital signal processor for the Parkes 21-cm multibeam receiver

Journal of Astronomical Instrumentation World Scientific Publishing 5:4 (2016)

Authors:

DC Price, L Staveley-Smith, M Bailes, E Carretti, A Jameson, Michael Jones, W van Straten, SW Schediwy

Abstract:

HIPSR (HI-Pulsar) is a digital signal processing system for the Parkes 21-cm Multibeam Receiver that provides larger instantaneous bandwidth, increased dynamic range, and more signal processing power than the previous systems in use at Parkes. The additional computational capacity enables finer spectral resolution in wideband HI observations and real-time detection of Fast Radio Bursts during pulsar surveys. HIPSR uses a heterogeneous architecture, consisting of FPGA-based signal processing boards connected via high-speed Ethernet to high performance compute nodes. Low-level signal processing is conducted on the FPGA-based boards, and more complex signal processing routines are conducted on the GPU-based compute nodes. The development of HIPSR was driven by two main science goals: to provide large bandwidth, high-resolution spectra suitable for 21-cm stacking and intensity mapping experiments; and to upgrade the Berkeley–Parkes–Swinburne Recorder (BPSR), the signal processing system used for the High Time Resolution Universe (HTRU) Survey and the Survey for Pulsars and Extragalactic Radio Bursts (SUPERB).