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Main Authors: Issifu, Adamu, Thakur, Prashant, da Silva, Franciele M., Marquez, Kau D., Menezes, Débora P., Dutra, M., Lourenço, O., Frederico, Tobias
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.17946
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author Issifu, Adamu
Thakur, Prashant
da Silva, Franciele M.
Marquez, Kau D.
Menezes, Débora P.
Dutra, M.
Lourenço, O.
Frederico, Tobias
author_facet Issifu, Adamu
Thakur, Prashant
da Silva, Franciele M.
Marquez, Kau D.
Menezes, Débora P.
Dutra, M.
Lourenço, O.
Frederico, Tobias
contents For the first time, we use relativistic mean-field (RMF) approximation with density-dependent couplings, adjusted by the DDME2 parameterization, to investigate the effects of dark matter on supernova remnants. We calculate the nuclear equation of state for nuclear and dark matter separately, under the thermodynamic conditions related to the evolution of supernova remnants. A mirrored model is adopted for dark matter, and its effect on remnant matter is studied using a two-fluid scenario. At each stage of the remnant evolution, we assume that dark and ordinary matter have the same entropy and lepton fraction, and a fixed proportion of dark matter mass fraction is added to the stellar matter to observe its effects on some microscopic and macroscopic properties of the star. We observe that dark matter in the remnant core reduces the remnant's maximum mass, radius, and tidal deformability. Moreover, dark matter heats the remnant matter and alters particle distributions, thereby decreasing its isospin asymmetry and increasing the sound speed through the matter.
format Preprint
id arxiv_https___arxiv_org_abs_2412_17946
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Supernova Remnants with Mirror Dark Matter and Hyperons
Issifu, Adamu
Thakur, Prashant
da Silva, Franciele M.
Marquez, Kau D.
Menezes, Débora P.
Dutra, M.
Lourenço, O.
Frederico, Tobias
High Energy Physics - Phenomenology
For the first time, we use relativistic mean-field (RMF) approximation with density-dependent couplings, adjusted by the DDME2 parameterization, to investigate the effects of dark matter on supernova remnants. We calculate the nuclear equation of state for nuclear and dark matter separately, under the thermodynamic conditions related to the evolution of supernova remnants. A mirrored model is adopted for dark matter, and its effect on remnant matter is studied using a two-fluid scenario. At each stage of the remnant evolution, we assume that dark and ordinary matter have the same entropy and lepton fraction, and a fixed proportion of dark matter mass fraction is added to the stellar matter to observe its effects on some microscopic and macroscopic properties of the star. We observe that dark matter in the remnant core reduces the remnant's maximum mass, radius, and tidal deformability. Moreover, dark matter heats the remnant matter and alters particle distributions, thereby decreasing its isospin asymmetry and increasing the sound speed through the matter.
title Supernova Remnants with Mirror Dark Matter and Hyperons
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2412.17946