Deformed Special Relativity with a minimum speed as explanation of the tiny value of the cosmological constant based on the Boomerang experiment in the CDM scenario

Abstract

In this paper we will show that a new structure of space-time with a minimum speed reveals a connection with Weyl geometry in the approximation of weak-field Newtonian limit. Symmetrical Special Relativity (SSR) has a minimum speed V that plays the role of a preferred reference frame SV of vacuum that leads to the cosmological constant . In order to realize such a connection between V and within a scenario of space-time metric, we will use a model of spherical universe with Hubble radius RH filled by a low vacuum energy density that governs the accelerated expansion of the universe. In doing this, we will show that SSR-metric plays the role of a de-Sitter (dS)-metric with a positive cosmological constant (>0). On the other hand, according to the Boomerang experiment as it is shown that the three-dimensional space of the universe is Euclidean and with a slightly accelerated expansion, SSR leads to a dS-metric with an approximation for <<1 close to a flat space-time, which is in the CDM scenario where the space is quasi-flat, so that m+≈ 1. We have cdm≈ 23\% by representing dark cold matter, m≈ 27\% for matter and ≈ 73\% for the vacuum energy. Thus, the theory is adjusted for redshift z=1, i.e., the time τ0 at which the universe goes over from a decelerating to an accelerating expansion by obtaining the numerical value 0=1.934× 10-35s-2, being in good agreement with measurements.