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Autori principali: Anchordoqui, Luis A., Halzen, Francis, Lust, Dieter
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.23414
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author Anchordoqui, Luis A.
Halzen, Francis
Lust, Dieter
author_facet Anchordoqui, Luis A.
Halzen, Francis
Lust, Dieter
contents The quantum gravity scale within the dark dimension scenario ($M_* \sim 10^{9}~{\rm GeV}$) roughly coincides with the energy scale of the KM3-230213A neutrino ($E_ν\sim 10^{8}~{\rm GeV}$). We propose an interpretation for this intriguing coincidence in terms of Hawking evaporation of five-dimensional (5D) primordial black holes (PBHs). 5D PBHs are bigger, colder, and longer-lived than 4D PBHs of the same mass. For brane observers, PBHs residing in the higher-dimensional bulk decay essentially invisibly (only through gravitationally and sterile coupled modes). As a consequence, constraints on the density of PBHs relative to that of dark matter from null searches of Hawking evaporation can be avoided. We demonstrate that Hawking evaporation of 5D bulk PBHs can explain the KM3-230213A neutrino, evade constraints from upper limits on the gamma-ray flux, and remain consistent with IceCube upper limits on the partial decay width of superheavy dark matter particles into neutrinos.
format Preprint
id arxiv_https___arxiv_org_abs_2505_23414
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Neutrinos from Primordial Black Holes in Theories with Extra Dimensions
Anchordoqui, Luis A.
Halzen, Francis
Lust, Dieter
High Energy Physics - Phenomenology
The quantum gravity scale within the dark dimension scenario ($M_* \sim 10^{9}~{\rm GeV}$) roughly coincides with the energy scale of the KM3-230213A neutrino ($E_ν\sim 10^{8}~{\rm GeV}$). We propose an interpretation for this intriguing coincidence in terms of Hawking evaporation of five-dimensional (5D) primordial black holes (PBHs). 5D PBHs are bigger, colder, and longer-lived than 4D PBHs of the same mass. For brane observers, PBHs residing in the higher-dimensional bulk decay essentially invisibly (only through gravitationally and sterile coupled modes). As a consequence, constraints on the density of PBHs relative to that of dark matter from null searches of Hawking evaporation can be avoided. We demonstrate that Hawking evaporation of 5D bulk PBHs can explain the KM3-230213A neutrino, evade constraints from upper limits on the gamma-ray flux, and remain consistent with IceCube upper limits on the partial decay width of superheavy dark matter particles into neutrinos.
title Neutrinos from Primordial Black Holes in Theories with Extra Dimensions
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2505.23414