A statistical representation of the cosmological constant from finite size effects at the apparent horizon

Abstract

In this paper we present a statistical description of the cosmological constant in terms of massless bosons (gravitons). To this purpose, we use our recent results implying a non vanishing temperature T for the cosmological constant. In particular, we found that a non vanishing T allows us to depict the cosmological constant as composed of elementary oscillations of massless bosons of energy ω by means of the Bose-Einstein distribution. In this context, as happens for photons in a medium, the effective phase velocity vg of these massless excitations is not given by the speed of light c but it is suppressed by a factor depending on the number of quanta present in the universe at the apparent horizon. We found interesting formulas relating the cosmological constant, the number of quanta N and the mean value λ of the wavelength of the gravitons. In this context, we study the possibility to look to the gravitons system so obtained as being very near to be a Bose-Einstein condensate. Finally, an attempt is done to write down the Friedmann flat equations in terms of N and λ.