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Autore principale: Cruz, Cláudio Nassif
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2409.04925
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author Cruz, Cláudio Nassif
author_facet Cruz, Cláudio Nassif
contents This research aims to provide the geometrical foundation of the uncertainty principle within a new causal structure of spacetime so-called Symmetrical Special Relativity (SSR), where there emerges a Lorentz violation due to the presence of an invariant minimum speed $V$ related to the vacuum energy. SSR predicts that a dS-scenario occurs only for a certain regime of speeds $v$, where $v<v_0=\sqrt{cV}$, which represents the negative gravitational potentials ($Φ<0$) connected to the cosmological parameter $Λ>0$. For $v=v_0$, Minkowski (pseudo-Euclidian) space is recovered for representing the flat space ($Λ=0$), and for $v>v_0$ ($Φ>0$), Anti-de Sitter (AdS) scenario prevails ($Λ<0$). The fact that the current universe is flat as its average density of matter distribution ($ρ_m$ given for a slightly negative curvature $R$) coincides with its vacuum energy density ($ρ_Λ$ given for a slightly positive curvature $Λ$), i.e., the {\it cosmic coincidence problem}, is now addressed by SSR. SSR provides its energy-momentum tensor of perfect fluid, leading to the EOS of vacuum ($p=-ρ_Λ$). Einstein equation for vacuum given by such SSR approach allows us to obtain $ρ_Λ$ associated with a scalar curvature $Λ$, whereas the solution of Einstein equation only in the presence of a homogeneous distribution of matter $ρ_m$ for the whole universe presents a scalar curvature $R$, in such a way that the presence of the background field $Λ$ opposes the Riemannian curvature $R$, thus leading to a current effective curvature $R_{eff}=R+Λ\approx 0$ according to observations.
format Preprint
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institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Lorentz violation with an invariant minimum speed as foundation of the uncertainty principle in Minkowski, dS and AdS spaces
Cruz, Cláudio Nassif
General Relativity and Quantum Cosmology
This research aims to provide the geometrical foundation of the uncertainty principle within a new causal structure of spacetime so-called Symmetrical Special Relativity (SSR), where there emerges a Lorentz violation due to the presence of an invariant minimum speed $V$ related to the vacuum energy. SSR predicts that a dS-scenario occurs only for a certain regime of speeds $v$, where $v<v_0=\sqrt{cV}$, which represents the negative gravitational potentials ($Φ<0$) connected to the cosmological parameter $Λ>0$. For $v=v_0$, Minkowski (pseudo-Euclidian) space is recovered for representing the flat space ($Λ=0$), and for $v>v_0$ ($Φ>0$), Anti-de Sitter (AdS) scenario prevails ($Λ<0$). The fact that the current universe is flat as its average density of matter distribution ($ρ_m$ given for a slightly negative curvature $R$) coincides with its vacuum energy density ($ρ_Λ$ given for a slightly positive curvature $Λ$), i.e., the {\it cosmic coincidence problem}, is now addressed by SSR. SSR provides its energy-momentum tensor of perfect fluid, leading to the EOS of vacuum ($p=-ρ_Λ$). Einstein equation for vacuum given by such SSR approach allows us to obtain $ρ_Λ$ associated with a scalar curvature $Λ$, whereas the solution of Einstein equation only in the presence of a homogeneous distribution of matter $ρ_m$ for the whole universe presents a scalar curvature $R$, in such a way that the presence of the background field $Λ$ opposes the Riemannian curvature $R$, thus leading to a current effective curvature $R_{eff}=R+Λ\approx 0$ according to observations.
title Lorentz violation with an invariant minimum speed as foundation of the uncertainty principle in Minkowski, dS and AdS spaces
topic General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2409.04925