Frequent flares from the nearby star TRAPPIST-1 could offer new clues in the search for habitable planets beyond Earth.<\/p>\n
TRAPPIST-1<\/a> is an ultracool red dwarf<\/a>, located about 40 light-years away in the constellation Aquarius. It hosts seven Earth-size planets, three of which orbit in the so-called “habitable zone” where liquid water might exist. However, the small star is notoriously active, erupting with energy bursts roughly six times per day, which can threaten planetary atmospheres within the system and obstruct observations, according to a statement from the University of Colorado Boulder.<\/p>\n <\/p>\n Using data from the James Webb Space Telescope<\/a> (JWST), researchers tracked six flares observed in 2022 and 2023. These flares appear as a big flash detectable by the JWST’s infrared sensors, revealing how much heat the star releases during an outburst. By combining these observations with computer simulations, the team reconstructed the physical processes driving each flare, allowing them to estimate the properties of the electron beams that trigger these stellar tantrums.<\/p>\n You may like<\/p>\n “If we can simulate these events using a computer model, we can reverse engineer how a flare<\/a> might influence the radiation environment around each of these planets,” Ward Howard, lead author of the study, said in the statement. This, in turn, can help determine which worlds might retain atmospheres capable of supporting life.<\/p>\n Surprisingly, the electron beams powering these flares appear about ten times weaker than those seen in similar stars<\/a>. That doesn’t mean they’re harmless \u2014 each flare emits radiation across the spectrum, from visible light to ultraviolet radiation and powerful X-rays, all of which can erode or alter planetary atmospheres over time.<\/p>\n As a result, the researchers suggested that the innermost TRAPPIST-1 planets may have lost their atmospheres, potentially leaving them as bare rocks, while one planet in the habitable zone<\/a>, TRAPPIST-1e, could still retain a thin, Earth-like atmosphere \u2014 a tentative sign that it might support conditions favorable to life.<\/p>\n By decoding TRAPPIST-1’s flare behavior, scientists can refine predictions about which planetary atmospheres might survive its constant outbursts. Rather than mere observational nuisances or purely destructive forces, these eruptions can be read as messages from the star, offering key insights into the potential habitability of its planets and informing the broader search for life beyond Earth<\/a>.<\/p>\n