Ricci-cubic holographic dark energy

TL;DR

This paper introduces a new holographic dark energy model based on cubic curvature invariants, which describes the universe's evolution through its present features and can replicate the entire thermal history.

Contribution

The paper proposes the Ricci-cubic holographic dark energy model using cubic curvature invariants, offering a more fundamental approach and analyzing its cosmological implications.

Findings

Model reproduces universe's thermal history from radiation to dark energy.

Equation of state exhibits quintessence, phantom-divide crossing, and phantom behavior.

Analytical solutions for key cosmological parameters are derived.

Abstract

In this work, we propose the Ricci-cubic holographic dark energy model. The model is inspired by the cubic curvature invariant formed by the contraction of three Riemann tensors. A combination of Ricci scalar and the cubic invariant is used to describe the infrared cutoff of the holographic dark energy. Such a construction is extremely useful since the evolution does not depend on the past or future features of the universe, but completely on its present features. Moreover, the use of invariants makes the theory more fundamental in nature. We have constructed the model and studied its cosmological features. The analytical solutions of various cosmological parameters such as the density parameter, equation of state parameter, and deceleration parameter are extracted and their behaviour is studied. It is seen that the holographic dark energy model can exhibit the entire thermal history of the universe, sequentially starting from radiation in the early universe, followed by matter, and finally the dark energy dominated epoch at late times. The equation of state parameter shows that the model can exhibit quintessence nature, phantom-divide crossing, and even phantom nature depending on the choice of parameter spaces.