Hintze Centre for Astrophysical Surveys

The dispersion-brightness relation for fast radio bursts from a wide-field survey

Nature Springer Nature 562 (2018) 386-390

Authors:

RM Shannon, J-P Macquart, KW Bannister, RD Ekers, CW James, S Osłowski, H Qiu, M Sammons, AW Hotan, MA Voronkov, RJ Beresford, M Brothers, AJ Brown, JD Bunton, AP Chippendale, C Haskins, M Leach, M Marquarding, D McConnell, MA Pilawa, EM Sadler, ER Troup, J Tuthill, MT Whiting, James Allison, CS Anderson, ME Bell, JD Collier, G Gürkan, G Heald, CJ Riseley

Abstract:

Despite considerable efforts over the past decade, only 34 fast radio bursts-intense bursts of radio emission from beyond our Galaxy-have been reported1,2. Attempts to understand the population as a whole have been hindered by the highly heterogeneous nature of the searches, which have been conducted with telescopes of different sensitivities, at a range of radio frequencies, and in environments corrupted by different levels of radio-frequency interference from human activity. Searches have been further complicated by uncertain burst positions and brightnesses-a consequence of the transient nature of the sources and the poor angular resolution of the detecting instruments. The discovery of repeating bursts from one source3, and its subsequent localization4 to a dwarf galaxy at a distance of 3.7 billion light years, confirmed that the population of fast radio bursts is located at cosmological distances. However, the nature of the emission remains elusive. Here we report a well controlled, wide-field radio survey for these bursts. We found 20, none of which repeated during follow-up observations between 185-1,097 hours after the initial detections. The sample includes both the nearest and the most energetic bursts detected so far. The survey demonstrates that there is a relationship between burst dispersion and brightness and that the high-fluence bursts are the nearby analogues of the more distant events found in higher-sensitivity, narrower-field surveys5.

Testing the magnetar scenario for superluminous supernovae with circular polarimetry

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 479:4 (2018) 4984-4990

Authors:

Aleksandar Cikota, Giorgos Leloudas, Mattia Bulla, Cosimo Inserra, Ting-Wan Chen, Jason Spyromilio, Ferdinando Patat, Zach Cano, Stefan Cikota, Michael W Coughlin, Erkki Kankare, Thomas B Lowe, Justyn R Maund, Armin Rest, Stephen J Smartt, Ken W Smith, Richard J Wainscoat, David R Young

KiDS0239-3211: A New Gravitational Quadruple Lens Candidate

Research Notes of the American Astronomical Society 2 (2018) 4

Authors:

A Sergeyev, C Spiniello, V Khramtsov, NR Napolitano, E Bannikova, C Tortora, FI Getman, A Agnello

The Lockman Hole Project: new constraints on the sub-mJy source counts from a wide-area 1.4 GHz mosaic

Monthly Notices of the Royal Astronomical Society Oxford University Press 481:4 (2018) 4548-4565

Authors:

I Prandoni, G Guglielmino, R Morganti, M Vaccari, A Maini, HJA Rottgering, Matthew Jarvis, MA Garrett

Abstract:

This paper is part of a series discussing the results obtained in the framework of a wide international collaboration - the Lockman Hole Project - aimed at improving the extensive multiband coverage available in the Lockman Hole region, through novel deep, wide-area, multifrequency (60, 150, 350 MHz, and 1.4 GHz) radio surveys. This multifrequency, multiband information will be exploited to get a comprehensive view of star formation and active galactic nucleus activities in the high-redshift Universe from a radio perspective. In this paper, we present novel 1.4 GHz mosaic observations obtained with the Westerbork Synthesis Radio Telescope. With an area coverage of 6.6 deg2, this is the largest survey reaching an rms noise of 11 μJy beam-1. In this paper, we present the source catalogue (~6000 sources with flux densities S ≳ 55 μJy (5σ), and we discuss the 1.4 GHz source counts derived from it. Our source counts provide very robust statistics in the flux range 0.1 < S < 1 mJy, and are in excellent agreement with other robust determinations obtained at lower and higher flux densities. A clear excess is found with respect to the counts predicted by the semi-empirical radio sky simulations developed in the framework of the Square Kilometre Array Simulated Skies project. A preliminary analysis of the identified (and classified) sources suggests this excess is to be ascribed to star-forming galaxies, which seem to show a steeper evolution than predicted.

The ATLAS All-Sky Stellar Reference Catalog

(2018)

Authors:

JL Tonry, L Denneau, H Flewelling, AN Heinze, CA Onken, SJ Smartt, B Stalder, HJ Weiland, C Wolf