Curvature Inspired Cosmological Scenario

TL;DR

This paper develops a cosmological model based on modified gravity with non-linear curvature terms, leading to a unified scenario that explains early inflation, late acceleration, and emergent dark sectors without dark energy as an independent component.

Contribution

It introduces a novel $f(R)$ gravity model with specific non-linear curvature terms that naturally produce dark matter, dark radiation, and dynamic dark energy behaviors.

Findings

Universe begins with power-law inflation.

Dark energy behaves as quintessence early and phantom late.

Dark matter and dark radiation emerge from gravitational sector.

Abstract

Using modified gravity with non-linear terms of curvature, $R^2$ and $R^{(r +2)}$ (with $r$ being the positive real number and $R$ being the scalar curvature), cosmological scenario,beginning at the Planck scale, is obtained. Here, a unified picture of cosmology is obtained from $f(R)-$ gravity. In this scenario, universe begins with power-law inflation, followed by deceleration and acceleration in the late universe as well as possible collapse of the universe in future. It is different from $f(R)-$ dark energy models with non-linear curvature terms assumed as dark energy. Here, dark energy terms are induced by linear as well as non-linear terms of curvature in Friedmann equation being derived from modified gravity.It is also interesting to see that, in this model, dark radiation and dark matter terms emerge spontaneously from the gravitational sector. It is found that dark energy, obtained here, behaves as quintessence in the early universe and phantom in the late universe. Moreover, analogous to brane-tension in brane-gravity inspired Friedmann equation, a tension term $\lambda$ arises here being called as cosmic tension. It is found that, in the late universe, Friedmann equation (obtained here) contains a term $- \rho^2/2\lambda$ ($\rho$ being the phantom energy density) analogous to a similar term in Friedmann equation with loop quantum effects, if $\lambda > 0$ and brane-gravity correction when $\lambda < 0.$