The achievement is no mean feat given the state of the telescope. The scientists recorded the bursts during a three-week period between July and August of 2018 while CHIME was still in a “pre-commissioning phase.” The project wasn’t yet living up to its full potential, suggesting that there are plenty more bursts to be discovered.

ALSO READ   Qualcomm just added $26 billion to its market cap in 2 days—Jim Cramer and other experts weigh in on its settlement with Apple - CNBC

It’s still not certain what creates these bursts. They could be the result of magnetars, or rapidly spinning neutron stars that have been strongly magnetized. Whatever the origin, their detection could provide valuable insights. Until now, there had only been one repeating fast radio burst — this provides valuable data. The University of Toronto’s Cherry Ng also told CNET that evidence of “scattering” (the effect of electrons and magnetic fields on the bursts’ long journey) could help pinpoint their origins.

ALSO READ   'Why are we so slow?' - Ferrari's Australian Grand Prix troubles revealed on team radio - ESPN

There’s one near-certainty: these bursts are likely to be much more common. If observers could find 13 such bursts this early into CHIME’s lifespan, there’s a real possibility that it will find others. Fast radio bursts might actually be common — it’s just that we’re only just noticing them.




Please enter your comment!
Please enter your name here