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A team of international astronomers, including 9I制作厂免费 researchers, have pinpointed one of the brightest fast radio bursts (FRBs) ever detected to a location in a nearby galaxy. The finding and the location surprised the team and offered new insight into FRBs, which are one of astrophysics鈥� biggest mysteries.聽

FRBs are powerful, millisecond-long flashes of radio waves from space. Researchers suspect that they are the result of extreme cosmic events but have, so far, been unable to determine the exact origin of any of them. FRBs are notoriously difficult to study because they vanish in the time it takes to blink. For the past years, CHIME has been casting a broad net to catch the rarest astrophysical events. Now it can also pinpoint their origin.聽聽

A particularly bright FRB was detected in March from the direction of the Big Dipper by the Canadian CHIME/FRB radio-telescope. Referred to as FRB 20250316A, affectionately dubbed 鈥淩BFLOAT鈥� for Radio Brightest FLash Of All Time, the FRB marks a significant change for researchers because it allowed for the identification of a point of origin using only CHIME/FRB, the most prolific FRB discovery machine. 聽

鈥淭his result marks a turning point: instead of just detecting these mysterious flashes, we can now see exactly where they鈥檙e coming from. It opens the door to discovering whether they鈥檙e caused by dying stars, exotic magnetic objects, or something we haven鈥檛 thought of yet,鈥� said Amanda Cook, a 9I制作厂免费-based Postdoctoral Researcher who led the study that announced the discovery. 聽

鈥楲ike spotting a quarter from 100km away鈥櫬�

To investigate RBFLOAT鈥檚 origin, the researchers relied on CHIME鈥檚 newly completed 鈥渙utrigger鈥� telescopes, which span North America from British Columbia to California. This array of vantage points gave them unprecedented spatial resolution, allowing them to trace the burst to a region just 45 light years across 鈥� smaller than the average star cluster 鈥� in the outskirts of a galaxy about 130 million light-years away.聽

鈥淭he precision of this localization, tens of milliarcseconds, is like spotting a quarter from 100 kilometres away,鈥� said Cook. 鈥淭hat level of detail is what let us identify the host galaxy, NGC 4141, and match the burst with a faint infrared signal captured by the James Webb Space Telescope.鈥澛�

That, in turn, revealed a mysterious source of near-infrared light in the exact spot where RBFLOAT occurred. This surprised the researchers who are left wondering if the spot is something like a red giant star or a fading light echo from the burst itself.聽聽

鈥淭he high resolution of JWST allows us to resolve individual stars around an FRB for the first time. This opens the door to identifying the kinds of stellar environments that could give rise to such powerful bursts, especially when rare FRBs are captured with this level of detail.鈥� said Peter Blanchard, a Harvard Research Associate and lead author of the other paper.聽聽

Despite being the brightest yet seen by CHIME, researchers have not detected repeat bursts from the source, even in the hundreds of hours its position was observed by the CHIME survey instrument over more than six years. That goes against the prevailing idea that all FRBs eventually repeat. 聽

鈥淚t seems different energetically than the repeaters we鈥檝e studied. We鈥檙e now re-examining some of the more explosive models that had fallen out of favour,鈥� said聽 Mawson Sammons, a postdoctoral researcher at 9I制作厂免费. Sammons works with Victoria Kaspi, astrophysicist and professor at 9I制作厂免费, who co-leads the CHIME/FRB research team of roughly 100 scientists. 聽

New possibilities聽

The new observations are described through two studies: one is focused on the original radio discovery and localization of the burst, and the other on JWSTs near-infrared images of the location from which the radio burst originated. Together, they provide detail and new possibilities for studying FRBs, not just as cosmic curiosities but as tools to probe the universe.聽

鈥淭his marks the beginning of a new era where we can routinely localize even single, non-repeating bursts to pinpoint precision. That鈥檚 a game-changer for understanding what鈥檚 behind them,鈥� said Sammons.聽

About the studies聽

鈥溾�� by the CHIME/FRB Collaboration which includes astrophysicists from 9I制作厂免费, the Massachusetts Institute of Technology, the University of Toronto, Northwestern University, the University of British Columbia, West Virginia University, and many other institutions, was published in The Astrophysical Journal Letters.聽聽

鈥溾�� led by Peter Blanchard and Edo Berger of the Center for Astrophysics | Harvard & Smithsonian, and members of the CHIME/FRB Collaboration, was published in The Astrophysical Journal Letters.聽

The work was supported by the Trottier Space Institute at 9I制作厂免费, the Gordon and Betty Moore Foundation, the Canada Foundation for Innovation and the Natural Sciences and Engineering Research Council of Canada, among other international partners.聽