Fast Radio Bursts (FRBs) are one of my favourite astronomical phenomena, because their cause or origin is still completely unknown. They are very short bursts of radio-frequency radiation, lasting just a few milliseconds, but of colossal intensity (the equivalent of 50 million times the sun’s energy in those few milliseconds). There have been only about 37 catalogued to date, all one-offs except FRB 121102.
FRB121102 is a “repeater” – a series of bursts were observed coming from the same source in 2012, then again on several days in 2015, and 15 more bursts during 30 minutes in 2017. The origin appears to be a galaxy about 2 billion light years away.
Although spinning black holes and neutron stars are possible candidate for generating the FRBs, there is no regularity of pulse in the transmissions as there is with spinning pulsars. One outside, but not discounted, possibility is that the source of the FRBs is some sort of extraterrestrial intelligent action – an attempt at communication or the utilisation of power for some purpose.
The new news is that researchers have re-analysed the data from August 26, 2017, when 21 bursts were detected, and they have found another 72 pulses by using AI – a convolutional neural network.
Update 8th Jan 2019: A new Canadian Observatory called CHIME has reported finding another 13 FRBs including another repeater.
Update 14th February 2019: Observations reported today suggest that Superluminous Supernovae give rise to magnetars that then emit FRBs. More observations to follow.
Update 27th Jun 2019: Astronomers using the Australian Square Kilometre Array Pathfinder (ASKAP), a network of 36 radio telescopes, can now auto-detect and successfully triangulate to pinpoint the source of FRBs. Today they detailed one from the outskirts of a very different type of galaxy than the repeater mentioned above. This weakens the existing theory of the cause of FRBs.
Update 15th August 2019: The Canadian Observatory called CHIME has reported detecting many more FRBs – importantly 8 more repeaters. Repeaters are especially important because they make it much easier to locate the exact source, and therefore to study that source with other instruments. Given the variation in time between repeats it could well be that all FRBs are repeaters – some are just more active than others. However the repeater bursts last a little longer than one-offs, and the repeaters all seem to exhibit a downward drift in frequency, with each burst getting lower. The source galaxies of the repeaters are now being determined by the direction from which the burst came, as well as the distance – which can be determined by the signal dispersion. Intriguingly, one of the repeaters is relatively close by. In addition the polarisation of the signal indicates how extreme was the magnetic environment at source. One of the new signals had very low polarisation so it is now known that not all FRBs originate near black-holes for example.