Saved in:
Bibliographic Details
Main Authors: Desai, Dhvanil D., Haggerty, Colby C., Shappee, Benjamin J., Tucker, Michael A., Davis, Zachary, Ashall, Chris, Chomiuk, Laura, Gootkin, Keyan, Caprioli, Damiano, Bret, Antoine, Hakobyan, Hayk
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.15335
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866918131453132800
author Desai, Dhvanil D.
Haggerty, Colby C.
Shappee, Benjamin J.
Tucker, Michael A.
Davis, Zachary
Ashall, Chris
Chomiuk, Laura
Gootkin, Keyan
Caprioli, Damiano
Bret, Antoine
Hakobyan, Hayk
author_facet Desai, Dhvanil D.
Haggerty, Colby C.
Shappee, Benjamin J.
Tucker, Michael A.
Davis, Zachary
Ashall, Chris
Chomiuk, Laura
Gootkin, Keyan
Caprioli, Damiano
Bret, Antoine
Hakobyan, Hayk
contents The light curves of radioactive transients, such as supernovae and kilonovae, are powered by the decay of radioisotopes, which release high-energy leptons through $β^+$ and $β^-$ decays. These leptons deposit energy into the expanding ejecta. As the ejecta density decreases during expansion, the plasma becomes collisionless, with particle motion governed by electromagnetic forces. In such environments, strong or turbulent magnetic fields are thought to confine particles, though the origin of these fields and the confinement mechanism have remained unclear. Using fully kinetic particle-in-cell (PIC) simulations, we demonstrate that plasma instabilities can naturally confine high-energy leptons. These leptons generate magnetic fields through plasma streaming instabilities, even in the absence of pre-existing fields. The self-generated magnetic fields slow lepton diffusion, enabling confinement and transferring energy to thermal electrons and ions. Our results naturally explain the positron trapping inferred from late-time observations of thermonuclear and core-collapse supernovae. Furthermore, they suggest potential implications for electron dynamics in the ejecta of kilonovae. We also estimate synchrotron radio luminosities from positrons for Type Ia supernovae and find that such emission could only be detectable with next-generation radio observatories from a Galactic or local-group supernova in an environment without any circumstellar material.
format Preprint
id arxiv_https___arxiv_org_abs_2504_15335
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Plasma Instabilities Dominate Radioactive Transients Magnetic Fields: The self-confinement of leptons in Type Ia and Core-Collapse Supernovae, and Kilonovae
Desai, Dhvanil D.
Haggerty, Colby C.
Shappee, Benjamin J.
Tucker, Michael A.
Davis, Zachary
Ashall, Chris
Chomiuk, Laura
Gootkin, Keyan
Caprioli, Damiano
Bret, Antoine
Hakobyan, Hayk
High Energy Astrophysical Phenomena
The light curves of radioactive transients, such as supernovae and kilonovae, are powered by the decay of radioisotopes, which release high-energy leptons through $β^+$ and $β^-$ decays. These leptons deposit energy into the expanding ejecta. As the ejecta density decreases during expansion, the plasma becomes collisionless, with particle motion governed by electromagnetic forces. In such environments, strong or turbulent magnetic fields are thought to confine particles, though the origin of these fields and the confinement mechanism have remained unclear. Using fully kinetic particle-in-cell (PIC) simulations, we demonstrate that plasma instabilities can naturally confine high-energy leptons. These leptons generate magnetic fields through plasma streaming instabilities, even in the absence of pre-existing fields. The self-generated magnetic fields slow lepton diffusion, enabling confinement and transferring energy to thermal electrons and ions. Our results naturally explain the positron trapping inferred from late-time observations of thermonuclear and core-collapse supernovae. Furthermore, they suggest potential implications for electron dynamics in the ejecta of kilonovae. We also estimate synchrotron radio luminosities from positrons for Type Ia supernovae and find that such emission could only be detectable with next-generation radio observatories from a Galactic or local-group supernova in an environment without any circumstellar material.
title Plasma Instabilities Dominate Radioactive Transients Magnetic Fields: The self-confinement of leptons in Type Ia and Core-Collapse Supernovae, and Kilonovae
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2504.15335