posted on 2024-08-06, 10:56authored byManisha Caleb, Christopher FlynnChristopher Flynn, Matthew BailesMatthew Bailes, Ewan Barr, T. Bateman, S. Bhandari, D. Campbell-Wilson, W. Farah, A. J. Green, R. W. Hunstead, A. Jameson, F. Jankowski, E. F. Keane, A. Parthasarathy, V. Ravi, P. A. Rosado, W. van Straten, V. Venkatraman Krishnan
We present the first interferometric detections of fast radio bursts (FRBs), an enigmatic new class of astrophysical transient. In a 180-d survey of the Southern sky, we discovered three FRBs at 843 MHz with the UTMOST array, as a part of commissioning science during a major ongoing upgrade. The wide field of view of UTMOST (approximate to 9 deg(2)) is well suited to FRB searches. The primary beam is covered by 352 partially overlapping fan -beams, each of which is searched for FRBs in real time with pulse widths in the range 0.655-42 ms, and dispersion measures <= 2000 pc cm(-3). Detections of FRBs with the UTMOST array place a lower limit on their distances of approximate to 10(4) km (limit of the telescope near -field) supporting the case for an astronomical origin. Repeating FRBs at UTMOST or an FRB detected simultaneously with the Parkes radio telescope and UTMOST would allow a few arcsec localization, thereby providing an excellent means of identifying FRB host galaxies, if present. Up to 100 h of followup for each FRB has been carried out with the UTMOST, with no repeating bursts seen. From the detected position, we present 3 sigma error ellipses of 15 arcsec x 8 degrees.4 on the sky for the point of origin for the FRBs. We estimate an all -sky FRB rate at 843 MHz above a fluence F-lim of 11 Jy ms of similar to 78 events sky(-1) d(-1) at the 95 per cent confidence level. The measured rate of FRBs at 843 MHz is two times higher than we had expected, scaling from the FRB rate at the Parkes radio telescope, assuming that FRBs have a flat spectral index and a uniform distribution in Euclidean space. We examine how this can be explained by FRBs having a steeper spectral index and/or a flatter logN-logF distribution than expected for a Euclidean Universe.
Funding
CE110001020:ARC
Exascale astronomy: real-time analysis of the transient radio universe