{"id":799146,"date":"2025-11-16T08:06:28","date_gmt":"2025-11-16T13:06:28","guid":{"rendered":"https:\/\/spaceweekly.com\/?p=799146"},"modified":"2025-11-16T08:06:28","modified_gmt":"2025-11-16T13:06:28","slug":"shape-of-a-supernova-detected-1-day-after-explosion","status":"publish","type":"post","link":"https:\/\/spaceweekly.com\/?p=799146","title":{"rendered":"Shape of a supernova detected 1 day after explosion"},"content":{"rendered":"


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This artist\u2019s impression shows a star going supernova. About 22 million light-years away, the supernova \u2013 SN 2024ggi \u2013 exploded in the galaxy NGC 3621. Using the ESO\u2019s Very Large Telescope, astronomers managed to capture the very early stage of the supernova when the blast was breaking through the star\u2019s surface. Observing the breakout so early on \u2013 just 26 hours after the supernova was first detected \u2013 revealed its true shape. The supernova broke out in an olive-like form. This marks the first ever observation of the shape of a supernova explosion at this very early stage. Image via ESO\/ L. Cal\u00e7ada.<\/figcaption><\/figure>\n

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  • Astronomers captured a supernova explosion just 26 hours after it began.<\/strong> They used ESO\u2019s Very Large Telescope to observe SN 2024ggi at the moment its shockwave burst through the star\u2019s surface.<\/li>\n
  • The blast was olive-shaped rather than spherical.<\/strong> It was the first time astronomers have seen a supernova explosion at its earliest stage.<\/li>\n
  • This knowledge enables astronomers to rule out some supernova models<\/strong> and add new information to improve others. It provides insights into the powerful deaths of massive stars.<\/li>\n<\/ul>\n

    ESO published this original story on November 12, 2025. Edits by EarthSky.<\/p>\n

    Shape of a supernova detected 1 day after explosion<\/h3>\n

    When the supernova explosion SN 2024ggi was first detected on the night of April 10, 2024, Yi Yang, an assistant professor at Tsinghua University in Beijing, China, and the lead author of the new study, had just landed in San Francisco after a long-haul flight. He knew he had to act quickly. Twelve hours later, he had sent an observing proposal to ESO, which, after a very quick approval process, pointed its Very Large Telescope (VLT) in Chile at the supernova on April 11, just 26 hours after the initial detection. <\/p>\n

    SN 2024ggi is in the galaxy NGC 3621 in the direction of the constellation Hydra. It\u2019s \u201conly\u201d 22 million light-years away, close by in astronomical terms. With a large telescope and the right instrument, the international team knew they had a rare opportunity to unravel the shape of the explosion shortly after it happened. Dietrich Baade, an ESO astronomer in Germany, is co-author of the peer-reviewed study published November 12, 2025, in Science Advances<\/em>. Baade said: <\/p>\n

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    The first VLT observations captured the phase during which matter \u2013 accelerated by the explosion near the center of the star \u2013 shot through the star\u2019s surface. For a few hours, the geometry of the star and its explosion could be, and were, observed together.<\/p>\n<\/blockquote>\n

    Yang said: <\/p>\n

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    The geometry of a supernova explosion provides fundamental information on stellar evolution and the physical processes leading to these cosmic fireworks. <\/p>\n<\/blockquote>\n