Our universe, filled with galaxies and stars, is full of mysteries. Over the centuries, astronomers have observed and documented supernova—the catastrophic explosion of stars—as some of the brightest and most energetic events in the universe. In particular, at the end of their lives, massive stars explode into core-collapse supernovae (CCSNe). Scientists believe these explosions to be mainly facilitated by neutrino-mediated energy transport. However, the effects of collective neutrino oscillations known as fast flavor conversion (FFC) on the CCSN explosion mechanism remain largely unclear.
Previous studies attempted to investigate the role of FFC in CCSNe using approximate “truncated moment” methods. However, these approaches cannot reliably capture the angular neutrino distributions needed to determine where FFC occurs.
A new study instead employs a multiangle treatment, allowing the researchers to directly model the angular behavior of neutrinos in momentum space.
The team of researchers, led by Assistant Professor/Junior Researcher Ryuichiro Akaho from the Faculty of Science and Engineering at Waseda University, Japan, along with co-authors Dr. Hiroki Nagakura from the National Astronomical Observatory of Japan and Professor Shoichi Yamada from Waseda University, has carried out CCSN simulations with multiangle neutrino transport to elucidate the impact of neutrino FFC on CCSNe. Their insightful findings were made available online on May 11, 2026, and have been published in Volume 136, Issue 19 of the journal Physical Review Letters on May 15, 2026. The paper was also selected as a “Featured in Physics” article by the journal editors, recognizing its significance and broad interest to the physics community.
In this study, the team combined a quantum kinetic theory-based FFC model with multidimensional Boltzmann neutrino radiation hydrodynamics simulations. Their framework directly identifies where FFC occurs using neutrino angular distributions calculated during the simulation itself. Akaho remarks: “We deploy our first-ever Boltzmann radiation hydrodynamics code that implements an FFC subgrid model, judge the occurrence of FFC directly from angular distributions obtained in simulations, and ascertain neutrino flavor states via physics-based quantum kinetic methods implemented through the Bhatnagar-Gross-Krook relaxation scheme. Crucially, we have already demonstrated this extended framework of neutrino transport in our previous work.”
The CCSN simulations presented in this study encompass successful as well as failed explosions, various progenitor models with zero-age main sequence masses of 9, 12, 16, and 20 M ⊙ , and three different nuclear equations of state (EOSs), namely, variational method-based Furusawa-Togashi EOS, Dirac-Brückner-Hartree-Fock technique, and chiral effective field theory.
The researchers remarkably found that the impact of FFC on CCSN explosion is bifurcated depending on the progenitors. While FFC promotes shock revival and boosts the explosion energy for the lowest-mass progenitor, it has an inhibitory impact for higher-mass progenitors. The mass accretion rate is the main determinant governing this bifurcated effect. For a high value of mass accretion rate, the contribution of FFC to neutrino heating turns out to be negative, since the concurrent reduction in neutrino luminosity dominates over the enhancement of heating efficiency through FFC-driven spectral hardening of electron-type neutrinos. In contrast, FFC contribution to neutrino heating becomes positive for a low mass accretion rate.
“Our present results highlight the limitations of approximate neutrino transport and show that a multiangle treatment is essential for accurately capturing FFC effects. Otherwise, important FFC signals may be overlooked or even falsely identified,” highlights Akaho.
Overall, this work provides a robust argument for the involvement of neutrino FFC in the explosion mechanism of CCSNe, improving our understanding of the lifecycle of massive stars and potentially serving as a theoretical guide for future CCSN observations.
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Reference
DOI: https://doi.org/10.1103/fksy-1jtw
Authors: Ryuichiro Akaho 1 , Hiroki Nagakura 2 , Wakana Iwakami 1 , Shun Furusawa 3 , Akira Harada 4,5 , Hirotada Okawa 6 , Hideo Matsufuru 7 , Kohsuke Sumiyoshi 8 , and Shoichi Yamada 1
Affiliations:
1 Faculty of Science and Engineering, Waseda University
2 Division of Science, National Astronomical Observatory of Japan
3 College of Science and Engineering, Kanto Gakuin University
4 Interdisciplinary Theoretical and Mathematical Sciences Program (iTHEMS), RIKEN
5 National Institute of Technology, Ibaraki College
6 Faculty of Software and Information Technology, Aomori University
7 High Energy Accelerator Research Organization
8 National Institute of Technology, Numazu College
About Waseda University
Located in the heart of Tokyo, Waseda University is a leading private research university that has long been dedicated to academic excellence, innovative research, and civic engagement at both the local and global levels since 1882. The University has produced many changemakers in its history, including eight prime ministers and many leaders in business, science and technology, literature, sports, and film. Waseda has strong collaborations with overseas research institutions and is committed to advancing cutting-edge research and developing leaders who can contribute to the resolution of complex, global social issues. The University has set a target of achieving a zero-carbon campus by 2032, in line with the Sustainable Development Goals (SDGs) adopted by the United Nations in 2015.
To learn more about Waseda University, visit https://www.waseda.jp/top/en
About Assistant Professor Ryuichiro Akaho from Waseda University
Dr. Ryuichiro Akaho is an Assistant Professor in the Faculty of Science and Engineering at Waseda University, Japan. His research focuses on computational astrophysics, neutrino radiation hydrodynamics, and the explosion mechanisms of core-collapse supernovae. He specializes in multidimensional Boltzmann neutrino transport simulations and studies the role of neutrino flavor conversion in massive stellar explosions. His work aims to advance the theoretical understanding of supernova dynamics and neutrino physics through large-scale numerical simulations.
Physical Review Letters
Computational simulation/modeling
Not applicable
Bifurcated Impact of Neutrino Fast Flavor Conversion on Core-Collapse Supernovae Informed by Multiangle Neutrino Radiation Hydrodynamics
15-May-2026
The authors declare no conflicts of interest.