A violent star explosion just revealed a hidden recipe for life
A supernova’s surprising chemical bounty reveals how stars forge some of life’s essential elements.
- Date:
- December 8, 2025
- Source:
- Kyoto University
- Summary:
- XRISM’s high-precision X-ray data revealed unusually strong signatures of chlorine and potassium inside the Cassiopeia A supernova remnant. These levels are far higher than theoretical models predicted, showing that supernovae can be major sources of these life-critical elements. Researchers believe powerful mixing deep inside massive stars is responsible for the unexpected boost. The findings reshape our understanding of how the building blocks of planets and life were created.
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"Why are we here?" remains one of the most enduring questions humans have posed. One way scientists approach this idea is by tracing where the elements around us first formed. Many elements are created inside stars and in the explosive debris of supernovae, which scatter this material across space, but the origins of several important elements have been difficult to explain.
Chlorine and potassium fall into this category. They are classified as odd-Z elements -- possessing an odd number of protons -- and are crucial for both life and the development of planets. Current models, however, indicate that stars should produce only about one-tenth of the chlorine and potassium that astronomers actually observe in the universe, leading to a long-standing scientific puzzle.
XRISM Offers a New Way to Study Supernova Debris
This gap in understanding led researchers at Kyoto University and Meiji University to investigate whether supernova remnants might hold the missing clues. They used XRISM -- short for X-Ray Imaging and Spectroscopy Mission, an X-ray satellite launched by JAXA in 2023 -- to gather high-resolution X-ray spectroscopic data from the Cassiopeia A supernova remnant in the Milky Way.
To accomplish this, the team relied on the microcalorimeter Resolve instrument on XRISM. The device provides energy resolution roughly ten times sharper than earlier X-ray detectors, which allowed the researchers to pick up faint emission lines associated with rare elements. After collecting the data from Cassiopeia A, they compared the measured amounts of chlorine and potassium with several theoretical models of how supernovae create elements.
Evidence That Supernovae Produce Life-Related Elements
The results showed clear X-ray emission lines of both chlorine and potassium at levels far higher than expected from standard models. This marks the first observational confirmation that a single supernova can generate enough of these elements to match what astronomers see in the cosmos. The researchers believe that strong internal mixing inside massive stars, possibly driven by rapid rotation, binary interactions, or shell-merger events, can greatly increase the production of these elements.
"When we saw the Resolve data for the first time, we detected elements I never expected to see before the launch. Making such a discovery with a satellite we developed is a true joy as a researcher," says corresponding author Toshiki Sato.
Insights Into How Stars Shape the Building Blocks of Life
These findings show that the chemical ingredients essential for life formed under extreme conditions deep within stars, far removed from anything resembling the environments where life later emerged. The work also demonstrates how powerful high-precision X-ray spectroscopy has become in uncovering the processes at work inside stellar interiors.
"I am delighted that we have been able, even if only slightly, to begin to understand what is happening inside exploding stars," says corresponding author Hiroyuki Uchida.
Next Steps for Understanding Stellar Evolution
The team plans to continue studying additional supernova remnants with XRISM to determine whether the elevated levels of chlorine and potassium found in Cassiopeia A are typical of massive stars or unique to this particular remnant. This will help reveal whether the internal mixing processes identified here are a widespread feature of stellar evolution.
"How Earth and life came into existence is an eternal question that everyone has pondered at least once. Our study reveals only a small part of that vast story, but I feel truly honored to have contributed to it," says corresponding author Kai Matsunaga.
Story Source:
Materials provided by Kyoto University. Note: Content may be edited for style and length.
Journal Reference:
- Marc Audard, Hisamitsu Awaki, Ralf Ballhausen, Aya Bamba, Ehud Behar, Rozenn Boissay-Malaquin, Laura Brenneman, Gregory V. Brown, Lia Corrales, Elisa Costantini, Renata Cumbee, Maria Diaz-Trigo, Chris Done, Tadayasu Dotani, Ken Ebisawa, Megan Eckart, Dominique Eckert, Teruaki Enoto, Satoshi Eguchi, Yuichiro Ezoe, Adam Foster, Ryuichi Fujimoto, Yutaka Fujita, Yasushi Fukazawa, Kotaro Fukushima, Akihiro Furuzawa, Luigi Gallo, Javier A. Garcia, Liyi Gu, Matteo Guainazzi, Kouichi Hagino, Kenji Hamaguchi, Isamu Hatsukade, Katsuhiro Hayashi, Takayuki Hayashi, Natalie Hell, Edmund Hodges-Kluck, Ann Hornschemeier, Yuto Ichinohe, Daiki Ishi, Manabu Ishida, Kumi Ishikawa, Yoshitaka Ishisaki, Jelle Kaastra, Timothy Kallman, Erin Kara, Satoru Katsuda, Yoshiaki Kanemaru, Richard Kelley, Caroline Kilbourne, Shunji Kitamoto, Shogo Kobayashi, Takayoshi Kohmura, Aya Kubota, Maurice Leutenegger, Michael Loewenstein, Yoshitomo Maeda, Maxim Markevitch, Hironori Matsumoto, Kyoko Matsushita, Dan McCammon, Brian McNamara, François Mernier, Eric D. Miller, Jon M. Miller, Ikuyuki Mitsuishi, Misaki Mizumoto, Tsunefumi Mizuno, Koji Mori, Koji Mukai, Hiroshi Murakami, Richard Mushotzky, Hiroshi Nakajima, Kazuhiro Nakazawa, Jan-Uwe Ness, Kumiko Nobukawa, Masayoshi Nobukawa, Hirofumi Noda, Hirokazu Odaka, Shoji Ogawa, Anna Ogorzalek, Takashi Okajima, Naomi Ota, Stephane Paltani, Robert Petre, Paul Plucinsky, Frederick Scott Porter, Katja Pottschmidt, Kosuke Sato, Toshiki Sato, Makoto Sawada, Hiromi Seta, Megumi Shidatsu, Aurora Simionescu, Randall Smith, Hiromasa Suzuki, Andrew Szymkowiak, Hiromitsu Takahashi, Mai Takeo, Toru Tamagawa, Keisuke Tamura, Takaaki Tanaka, Atsushi Tanimoto, Makoto Tashiro, Yukikatsu Terada, Yuichi Terashima, Yohko Tsuboi, Masahiro Tsujimoto, Hiroshi Tsunemi, Takeshi G. Tsuru, Hiroyuki Uchida, Nagomi Uchida, Yuusuke Uchida, Hideki Uchiyama, Yoshihiro Ueda, Shinichiro Uno, Jacco Vink, Shin Watanabe, Brian J. Williams, Satoshi Yamada, Shinya Yamada, Hiroya Yamaguchi, Kazutaka Yamaoka, Noriko Yamasaki, Makoto Yamauchi, Shigeo Yamauchi, Tahir Yaqoob, Tomokage Yoneyama, Tessei Yoshida, Mihoko Yukita, Irina Zhuravleva, Shin-ichiro Fujimoto, Kai Matsunaga, Manan Agarwal. Chlorine and potassium enrichment in the Cassiopeia A supernova remnant. Nature Astronomy, 2025; DOI: 10.1038/s41550-025-02714-4
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