Space'Anti-social' cosmic explosion challenges current understanding of supernovasRobert Lea
Thu, October 30, 2025 at 4:00 PM EDT
6 min read
A composite image of the Cassiopeia A Type II supernova remnant produced with data from NASA's Chandra X-ray Observatory and the James Webb Space Telescope. | Credit: X-ray: NASA/CXC/SAO; Optical: NASA/ESA/STScI; IR: NASA/ESA/CSA/STScI/Milisavljevic et al., NASA/JPL/CalTech; Image Processing: NASA/CXC/SAO/J. Schmidt and K. ArcandAn investigation of a cosmic explosion that marked the violent death of a massive star has called into question our understanding of the connection between ejected debris violently striking surrounding matter and the energy output of these events.
The supernova at the heart of this research, designated SN 2024bch, erupted around 65 million light-years away from Earth and was first observed in February 2024. It is an example of a Type II supernova, an explosion that occurs when nuclear fusion ceases in the solid iron core of a massive star, causing it to collapse, sending shockwaves into the star's outer layers, leading to them being ejected.
Scientists have always assumed that when this stellar ejecta violently slams into dense gas surrounding the dying star, known as the circumstellar medium, this generates narrow emission lines in the light or spectra seen from Type II supernovas. However, SN 2024bch seems to be "anti-social", in that its ejected matter seems to not interact violently with a surrounding gas shell. However, these narrow lines are still apparent in its spectra.
The team behind this research, hailing from the National Institute for Astrophysics (INAF), studied this supernova for 140 days, using a range of ground-based telescopes and the Swift spacecraft, discovering the narrow emission lines in its spectra. This feature has previously been considered a test for discovering if a dying star is interacting with its environment.
However, in the case of SN 2024bch, the released energy doesn't seem to be the result of ejected matter mixing with a dense gas shell. Instead, the INAF researchers suggest a different mechanism to account for the energy, termed Bowen fluorescence.
"We applied a non-traditional and unprejudiced perspective," Leonardo Tartaglia, team leader and INAF researcher, said in a translated statement." For the first time in this type of transient, we demonstrate that the primary mechanism is Bowen fluorescence, a phenomenon known since the first half of the 20th century that had never been considered in the study of similar objects. Our scenario describes all the evolutionary phases of the supernova with great precision."
Bowen fluorescence is akin to an echo but of high-energy light rather than sound. In this case, intense ultraviolet light from the supernova excites surrounding helium atoms, and these atoms then transfer energy to other elements like oxygen and nitrogen also present around the dying star. It is this transfer of energy that generates the narrow spectral lines seen by the team.
This revelation means scientists might have to rethink Type II supernova models, which would result in some of these cosmic explosions being ruled out as a source of neutrinos, virtually massless, chargeless "ghost particles" that stream through space at near light-speed.
This could have ramifications for a powerful method of investigating the cosmos called multimessenger astronomy, which involves studying events and objects in electromagnetic radiation along with gravitational waves or neutrinos.
"Our study highlights that, for at least a fraction of these transients, interaction is not the primary driver of emissions, and this has important implications for multi-messenger astronomy," Tartaglia said. "Showing no evidence of interaction, supernova SN 2024bch lacks the physical conditions necessary for the emission of high-energy neutrinos."
The team's research has been accepted for
publication in Astronomy & Astrophysics.
https://www.yahoo.com/news/articles/anti-social-cosmic-explosion-challenges-200000939.html
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