Dark gauge boson emission from supernova pions

Chang Sub Shin; Seokhoon Yun

doi:10.1103/PhysRevD.108.055014

Dark gauge boson emission from supernova pions

Chang Sub Shin
, Seokhoon Yun

Department of Physics

Chungnam National University
Institute for Basic Science
Korea Institute for Advanced Study

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

The hot, neutron-rich, and dense circumstance in core-collapse supernovae provides a source of negatively charged pions that may make up a significant portion of the matter. These abundant thermal pions offer an opportunity to populate light and hidden hypothetical particles. In this study, we discuss the dark gauge boson production via reactions involving supernova pions. The rate of this production is determined by the isovector nucleon coupling. We consider two toy models, the dark photon and the gauged B-L models, that carry the typical distinct isovector nucleon coupling structure in the medium. Pion-induced dark gauge bosons leave an imprint on several observational consequences associated with supernova. Their sizable emissivity and characteristic hard spectral distribution result in the stringent constraints on the dark gauge boson models, in particular at masses above the two electron mass.

Original language	English
Article number	055014
Journal	Physical Review D
Volume	108
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevD.108.055014
State	Published - 1 Sep 2023

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title = "Dark gauge boson emission from supernova pions",

abstract = "The hot, neutron-rich, and dense circumstance in core-collapse supernovae provides a source of negatively charged pions that may make up a significant portion of the matter. These abundant thermal pions offer an opportunity to populate light and hidden hypothetical particles. In this study, we discuss the dark gauge boson production via reactions involving supernova pions. The rate of this production is determined by the isovector nucleon coupling. We consider two toy models, the dark photon and the gauged B-L models, that carry the typical distinct isovector nucleon coupling structure in the medium. Pion-induced dark gauge bosons leave an imprint on several observational consequences associated with supernova. Their sizable emissivity and characteristic hard spectral distribution result in the stringent constraints on the dark gauge boson models, in particular at masses above the two electron mass.",

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N2 - The hot, neutron-rich, and dense circumstance in core-collapse supernovae provides a source of negatively charged pions that may make up a significant portion of the matter. These abundant thermal pions offer an opportunity to populate light and hidden hypothetical particles. In this study, we discuss the dark gauge boson production via reactions involving supernova pions. The rate of this production is determined by the isovector nucleon coupling. We consider two toy models, the dark photon and the gauged B-L models, that carry the typical distinct isovector nucleon coupling structure in the medium. Pion-induced dark gauge bosons leave an imprint on several observational consequences associated with supernova. Their sizable emissivity and characteristic hard spectral distribution result in the stringent constraints on the dark gauge boson models, in particular at masses above the two electron mass.

AB - The hot, neutron-rich, and dense circumstance in core-collapse supernovae provides a source of negatively charged pions that may make up a significant portion of the matter. These abundant thermal pions offer an opportunity to populate light and hidden hypothetical particles. In this study, we discuss the dark gauge boson production via reactions involving supernova pions. The rate of this production is determined by the isovector nucleon coupling. We consider two toy models, the dark photon and the gauged B-L models, that carry the typical distinct isovector nucleon coupling structure in the medium. Pion-induced dark gauge bosons leave an imprint on several observational consequences associated with supernova. Their sizable emissivity and characteristic hard spectral distribution result in the stringent constraints on the dark gauge boson models, in particular at masses above the two electron mass.

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Dark gauge boson emission from supernova pions

Abstract

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