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Main Author: Bernabeu, Jose
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.09419
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author Bernabeu, Jose
author_facet Bernabeu, Jose
contents Massive stellar gravitational collapse is not an endless process. The Standard Model of particle physics predicts the existence of a repulsive interaction, two-neutrino mediated, with a coherent weak charge of macroscopic matter proportional to the number of constituents. After gravity, this is the second longest range -- microns -- force and, below nanometers, its magnitude overcomes the attractive gravitation. The layer distribution of pressure inside a compact neutronized uniform sphere, independent of its size, is compared for the two interactions with opposite pressure gradient. Taking as reference the mean square radius, the volume evolution of the pressure, for fixed mass and weak charge, leads to an equilibrium scenario with a characteristic black-hole radius $R_B = 1.58$ nm. This size scale should be universal, independent of the mass, as long as the mass is nearly proportional to the weak charge.
format Preprint
id arxiv_https___arxiv_org_abs_2312_09419
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle No space-time singularity in black-hole physics
Bernabeu, Jose
General Physics
Massive stellar gravitational collapse is not an endless process. The Standard Model of particle physics predicts the existence of a repulsive interaction, two-neutrino mediated, with a coherent weak charge of macroscopic matter proportional to the number of constituents. After gravity, this is the second longest range -- microns -- force and, below nanometers, its magnitude overcomes the attractive gravitation. The layer distribution of pressure inside a compact neutronized uniform sphere, independent of its size, is compared for the two interactions with opposite pressure gradient. Taking as reference the mean square radius, the volume evolution of the pressure, for fixed mass and weak charge, leads to an equilibrium scenario with a characteristic black-hole radius $R_B = 1.58$ nm. This size scale should be universal, independent of the mass, as long as the mass is nearly proportional to the weak charge.
title No space-time singularity in black-hole physics
topic General Physics
url https://arxiv.org/abs/2312.09419