Unraveling the Role of Neutrino Processes on the Astrophysical Production of 94Mo

Unraveling the Role of Neutrino Processes on the Astrophysical Production of 94Mo

The enigmatic origin of the proton-rich nuclei ^92 Mo and ^94 Mo in the solar system remains one of the most intriguing mysteries in astrophysics, with the definitive production site yet to be identified. Although mechanisms such as the proton-capture reactions, photonuclear reactions, and neutrino...

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Bibliographic Details
Main Authors: N. Song, Z. H. Li, G. X. Li, Z. C. Gao, Y. F. Niu
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:The Astrophysical Journal
Subjects:
Core-collapse supernovae
Supernova neutrinos
P-process
Solar abundances
Online Access:https://doi.org/10.3847/1538-4357/adf746
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Summary:The enigmatic origin of the proton-rich nuclei ^92 Mo and ^94 Mo in the solar system remains one of the most intriguing mysteries in astrophysics, with the definitive production site yet to be identified. Although mechanisms such as the proton-capture reactions, photonuclear reactions, and neutrino processes have been proposed, the underproduction of ^94 Mo persists as a puzzle. In this study, we investigate the production of ^94 Mo through neutrino-induced processes during core-collapse supernova explosions. By calculating the cross sections of the charged-current reactions ^94 Zr ( ν _e , e ^− ) ^94 Nb and ^95 Mo ( ν _e , e ^− p) ^94 Mo, as well as the neutral-current reactions ^95 Mo $\,(\nu ,{\nu }^{{\prime} }$ n) ^94 Mo, based on supernova explosion models, we explore the contribution of neutrino-nucleus reactions to the abundance of ^94 Mo. Our results indicate that these neutrino-induced reactions can account for up to 6.8% of the solar system abundance of ^94 Mo. Additionally, we propose that specific temperatures and proton number densities formed by neutrino shock waves could reproduce the solar system abundance ratio of ^94 Mo to ^92 Mo. This work provides a new perspective on understanding the origin of p -process nuclei in the solar system and establishes a significant theoretical foundation for future research endeavors.
ISSN:1538-4357

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