Baryogenesis via Hawking-like Radiation in the FRW Space-time

TL;DR

This paper proposes a model where Hawking-like radiation in FRW spacetime causes baryogenesis by creating a baryon asymmetry, aligning with observed cosmic parameters and potentially connecting quantum gravity, inflation, and baryon asymmetry.

Contribution

It introduces a novel coupling between Ricci scalar derivatives and the B-L current to explain baryogenesis within a phenomenological framework.

Findings

Baryon asymmetry generated mainly at the Universe's beginning.

Model predicts a higher inflation energy scale consistent with GUT.

Correct CMB photon temperature at decoupling.

Abstract

We present a phenomenological model for baryogenesis based on particle creation in the Friedman-Robertson-Walker (FRW) spacetime. This study is a continuation of our proposal that Hawking-like radiation in FRW space-time explains several physical aspects of the early Universe including inflation. In this model we study a coupling between the FRW space-time, in the form of the derivative of the Ricci scalar, and the $B-L$ current, $J^{\mu} _{B-L}$, which leads to a different chemical potential between baryons and anti-baryons resulting in an excess of baryons over anti-baryons with the right order of magnitude. In this model the generation of baryon asymmetry, in principle, occurs over the entire history of the Universe starting from the beginning of the radiation phase. However, in practice, almost the entire contribution to the baryon asymmetry only comes from the very beginning of the Universe and is negligible thereafter. There is a free parameter in our model which can be interpreted as defining the boundary between the unknown quantum gravity regime and the inflation/baryogenesis regime covered by our model. When this parameter is adjusted to give the observed value of baryon asymmetry we get a higher than usual energy scale for our inflation model which however may be in line with the GUT scale for inflation in view of the BICEP2 and Planck results. In addition our model provides the correct temperature for the CMB photons at the time of decoupling.