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\t\t\t\t\t\t18\/03\/2026<\/span> Comet K1, whose full name is Comet C\/2025 K1 (ATLAS), had just passed its closest approach to the Sun and was heading out of the Solar System. Though it had been intact just days before, K1 fragmented into at least four pieces while the NASA\/ESA Hubble Space Telescope was watching. The odds of that happening while Hubble viewed the comet are extraordinarily miniscule.<\/p>\n<\/div>\n Comet K1, whose full name is Comet C\/2025 K1 (ATLAS)\u00a0\u2013 not to be confused with interstellar comet 3I\/ATLAS\u00a0\u2013 was not the original target of a recent Hubble study.\u00a0The findings were published today in the journal\u00a0Icarus.<\/i><\/p>\n \u201cSometimes the best science happens by accident,\u201d\u00a0said co-investigator John Noonan, a research professor in the Department of Physics at Auburn University in Alabama in the United States.\u00a0\u201cThis comet got observed because our original comet was not viewable due to some new technical constraints after we won our proposal. We had to find a new target\u00a0\u2013 and right when we observed it, it happened to break apart, which is the slimmest of slim chances.\u201d<\/p>\n John\u00a0didn\u2019t know K1 was fragmenting until he viewed the images the day after Hubble took them.\u00a0\u201cWhile I was taking an initial look at the data, I saw that there were four comets in those images when we only proposed to look at one,\u201d\u00a0said John.\u00a0\u201cSo we knew this was something really, really special.\u201d<\/p>\n This is an experiment the researchers always wanted to do with Hubble. They had proposed many Hubble observations to catch a\u00a0comet\u00a0breaking up. Unfortunately, these are very difficult to schedule, and they were never successful.<\/p>\n \u201cThe irony is now we\u2019re just studying a regular comet and it crumbles in front of our eyes,\u201d\u00a0said principal investigator Dennis Bodewits, also a professor in Auburn University\u2019s Department of Physics.<\/p>\n \u201cComets are leftovers of the era of Solar System formation, so they\u2019re made of \u2018old stuff\u2019 \u2013\u00a0the primordial materials that made our Solar System,\u201d\u00a0explained Dennis.\u00a0\u201cBut they are not pristine \u2013\u00a0they\u2019ve been heated, they\u2019ve been irradiated by the Sun and by cosmic rays. So, when looking at a comet\u2019s composition, the question that we always have is, \u2018Is this a primitive property or is this due to evolution?\u2019 By cracking open a comet, you can see the ancient material that has not been processed.\u201d<\/p>\n Hubble caught K1 fragmenting into at least four pieces, each with a distinct coma, the fuzzy envelope of gas and dust that surrounds a comet\u2019s icy nucleus. Hubble cleanly resolved the fragments, but to ground-based telescopes, at they time they only appeared as barely distinguishable blobs.<\/p>\n Hubble\u2019s images were taken just a month after K1\u2019s closest approach to the Sun, called perihelion. The comet’s\u00a0perihelion was inside Mercury\u2019s orbit, about one-third the distance of the Earth from the Sun. During perihelion, a comet experiences its most intense heating and maximum stress. Just past perihelion is when some long-period comets like K1 tend to fall apart.<\/p>\n Before it fragmented, K1 was likely a bit larger than an average comet, probably around 8 km across. The team estimates the comet began to disintegrate eight days before Hubble viewed it. Hubble took three 20-second images, one on each day from 8 November through 10 November 2025. As it watched the comet, one of K1\u2019s smaller pieces also broke up.<\/p>\n<\/p><\/div>\n Because Hubble\u2019s sharp vision can distinguish extremely fine details, the team could trace the history of the fragments back to when they were one piece. That allowed them to reconstruct the timeline. But in doing so, they uncovered a mystery: Why was there a delay between when the comet broke up and when bright outbursts were seen from the ground? When the comet fragmented and exposed fresh ice, why didn\u2019t it brighten almost instantaneously?<\/p>\n The team has some theories. Most of a comet\u2019s brightness is sunlight reflected off of dust grains. But when a comet cracks open, it reveals pure ice. Maybe a layer of dry dust needs to form over the pure ice and then blow off. Or maybe heat needs to get below the surface, build up pressure, and then eject an expanding shell of dust.<\/p>\n \u201cNever before has Hubble caught a fragmenting comet this close to when it actually fell apart. Most of the time, it\u2019s a few weeks to a month later. And in this case, we were able to see it just days after,\u201d\u00a0said John.\u00a0\u201cThis is telling us something very important about the physics of what\u2019s happening at the comet\u2019s surface. We may be seeing the timescale it takes to form a substantial dust layer that can then be ejected by the gas.\u201d<\/p>\n As exciting as these findings are, the best is yet to come. The team is looking forward to finishing the analysis of the gases to come from the comet. Already, ground-based analysis shows that K1 is chemically very strange\u00a0\u2013 it is significantly depleted in carbon, compared with other comets. Spectroscopic analysis from Hubble\u2019s STIS (Space Telescope Imaging Spectrograph) and COS (Cosmic Origins Spectrograph) instruments is likely to reveal much more about the composition of K1 and the very origins of our Solar System.<\/p>\n The comet\u00a0K1 is now a collection of fragments about 400 million km from Earth. Located in the constellation Pisces, it is heading out of the Solar System, not likely to ever return. Astronomers see that long-period comets such as K1 are more likely to fragment than their short-period cousins, such as 67P\/Churyumov-Gerasimenko that was visited by ESA\u2019s\u00a0Rosetta mission, but it is not known why. Launching towards the end of the decade, ESA\u2019s\u00a0Comet Interceptor\u00a0will be the first mission to visit a long-period comet. \u201cHubble\u2019s chance observation of K1 will help us understand why some long-period comets split apart and give us a first view of their interiors,\u201d\u00a0said co-author Prof. Colin Snodgrass of the University of Edinburgh in Scotland and an Interdisciplinary Scientist for the Comet Interceptor mission.\u00a0\u201cThese new results will complement the detailed view of a long-period comet that we will obtain from Comet Interceptor, as well as helping astronomers to select the\u00a0mission\u2019s target.\u201d<\/p>\n<\/p><\/div>\n
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