Astronomers closer to cracking mystery of fast radio bursts – Nature.com
The CHIME telescope in Canada searches the sky for highly energetic cosmic events called fast radio bursts.Credit: CHIME Collaboration
Astronomers are edging closer to discovering what causes brief, powerful flashes in the sky known as fast radio bursts (FRBs), after a Canadian telescope discovered eight more of the most intriguing type of these blasts — those that repeat their signals.
FRBs are intensely energetic events that flare for just milliseconds, seemingly all over the sky and from outside the galaxy. But their cause has remained a mystery since the first FRB was identified in 2007. Astronomers hope that studying bursts that repeat their flashes, rather than just flare once, can help to elucidate the origins of FRBs. That’s because it’s easier for high-resolution telescopes to make follow-up observations of ‘repeaters’ and trace their origins than of one-off blasts.
Of the roughly 75 FRBs seen before now, just two bursts were known to be repeaters. The first of these has been extensively studied, and the Canadian Hydrogen Intensity Mapping Experiment (CHIME) telescope discovered the second repeater earlier this year. CHIME’s latest results, published1 on the arXiv preprint server on 9 August, now show that repeaters are far from rare. In the past few weeks, another telescope, the Australian Square Kilometre Array Pathfinder, also found a repeater, bringing the total so far to 11 — although researchers are yet to publish this result.
CHIME, which began hunting for FRBs in 2018, has also discovered hundreds of one-off FRBs, CHIME researcher Bryan Gaensler said on Twitter on 12 August. Members of the telescope collaboration are still analysing these events, said Gaensler, an astronomer at the University of Toronto. “In 25 years of astronomy research, this is unquestionably the most exciting project I’ve ever worked on,” he said.
Scattered events
“This is a pretty exciting result,” says Laura Spitler at the Max Planck Institute for Radio Astronomy in Bonn, Germany. Astronomers’ priority will be to search for the host galaxy of these repeat signals, she says. Pinpointing the host galaxies is essential to cracking the mystery of what causes FRBs. And sketching a picture of the environments in which they are born will allow researchers to whittle down some of the dozens of possible explanations for the blasts. Astronomers suggest that they could be emissions from young magnetars, dense star cores spinning in a magnetic field, or vibrating cosmic strings.
The findings mean there are enough repeaters to start comparing these with one-off blasts, to find out whether the two kinds of FRB are produced in similar environments, says Spitler. All FRBs could come from fundamentally similar environments, perhaps with repeat blasts avoiding detection, or sources only flaring under certain conditions. By contrast, each type could be caused by different events — one that repeats and one that doesn’t.
The CHIME team has already seen clues that could help to answer this question. The eight repeaters seem to be located within a similar range of distances to the one-off bursts. But repeater signals lasted longer on average, the collaboration reports. Spitler says that, if this trend holds, it could be a sign that two different phenomena cause the different types of blast because a burst’s duration reflects the underlying mechanism that produces it.
Elusive environments
The latest data reveal differences in the environments from which repeaters emanate. A previously discovered repeater, FRB121102 — the only repeating signal whose precise host galaxy has been identified — came from a highly magnetized environment. Like FRB121102, the signal of one of the latest bursts is polarized with a spiral pattern that suggests it comes through a magnetic field. But the strength of the field for the new repeater is around 100 times weaker than that of FRB121102’s.
Many, although not all, of the latest haul also share a feature of the first two repeaters. Rather than being a simple blast that is narrow in frequency, the signals descend in frequency in a way that the team compares to a ‘sad trombone’ sound. “Such ‘sad trombone’ signals are actually rather unusual and complicated,” says Spitler. Explaining them poses a challenge to theorists, she adds.
The findings are only a small preview of the “full awesomeness coming out of CHIME”, said Gaensler. The telescope, which is in Penticton, British Columbia, was initially built to study radiowaves from the early Universe. But in 2013, astronomers realized that the half-pipe-shaped telescope, which every day sweeps almost the entire northern sky, could also spot FRBs. For the relatively cheap cost of $16 million, they turned CHIME into an FRB-hunter. Astronomers had only recently begun to take the telescope seriously, after initial observations appeared to be caused by interference or instrumental glitches.
“CHIME is definitely living up to its promise”, says Spitler.
