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Main Authors: Shi, Haihao, Huang, Zhenyang, Zhou, Junda, Lü, Guoliang, Chen, Xuefei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.16631
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author Shi, Haihao
Huang, Zhenyang
Zhou, Junda
Lü, Guoliang
Chen, Xuefei
author_facet Shi, Haihao
Huang, Zhenyang
Zhou, Junda
Lü, Guoliang
Chen, Xuefei
contents We introduce a novel parameterization of supernova neutrino energy spectra with a clear physical motivation. Its central parameter, $τ(t)$, quantifies the characteristic thermal-diffusion area during the explosion. When applied to the historic SN1987A data, this parameterization yields statistically significant fits and provides robust constraints on the unobserved low-energy portion of the spectrum. Beyond this specific application, we demonstrate the model's power on a suite of 3D core-collapse supernova simulations, finding that the temporal evolution of $τ(t)$ distinctly separates successful from failed explosions. Furthermore, we constrain the progenitor mass of SN 1987A to approximately 19 solar masses by applying Smoothed Isotonic Regression, while noting the sensitivity of this estimate to observational uncertainties. Moreover, in these simulations, $τ(t)$ and the gravitational-wave strain amplitude display a strong, synergistic co-evolution, directly linking the engine's energetic evolution to its geometric asymmetry. This implies that the thermodynamic state of the explosion is imprinted not only on the escaping neutrino flux, but also recorded in the shape of the energy spectrum. Our framework therefore offers a valuable tool for decoding the detailed core dynamics and multi-messenger processes of future galactic supernovae.
format Preprint
id arxiv_https___arxiv_org_abs_2511_16631
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Core-Collapse Supernova Neutrino Parameterization with Enhanced Physical Interpretability
Shi, Haihao
Huang, Zhenyang
Zhou, Junda
Lü, Guoliang
Chen, Xuefei
High Energy Astrophysical Phenomena
We introduce a novel parameterization of supernova neutrino energy spectra with a clear physical motivation. Its central parameter, $τ(t)$, quantifies the characteristic thermal-diffusion area during the explosion. When applied to the historic SN1987A data, this parameterization yields statistically significant fits and provides robust constraints on the unobserved low-energy portion of the spectrum. Beyond this specific application, we demonstrate the model's power on a suite of 3D core-collapse supernova simulations, finding that the temporal evolution of $τ(t)$ distinctly separates successful from failed explosions. Furthermore, we constrain the progenitor mass of SN 1987A to approximately 19 solar masses by applying Smoothed Isotonic Regression, while noting the sensitivity of this estimate to observational uncertainties. Moreover, in these simulations, $τ(t)$ and the gravitational-wave strain amplitude display a strong, synergistic co-evolution, directly linking the engine's energetic evolution to its geometric asymmetry. This implies that the thermodynamic state of the explosion is imprinted not only on the escaping neutrino flux, but also recorded in the shape of the energy spectrum. Our framework therefore offers a valuable tool for decoding the detailed core dynamics and multi-messenger processes of future galactic supernovae.
title A Core-Collapse Supernova Neutrino Parameterization with Enhanced Physical Interpretability
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2511.16631