On a model of variable curvature that mimics the observed Universe acceleration

We present a new model based on General Relativity in where a subtle change of curvature at late times is able to produce the observed Universe acceleration and an oscillating behavior in the effective equation of state, similar to what has been claimed by recent results from the Dark Energy Spectroscopic Instrument and Baryon Acoustic Oscillation observations. This model is reassembled in the gap between traditional FLRW homogeneous and isotropic models and those Stephani models providing inhomogeneity functions in the time derivatives to explore other forms of varying curvature functions. Remarkably, in addition to an accelerated phase close to the usual $\Lambda$CDM equivalent transition from decelerated to accelerated Universe at $z \sim 0.6$, we also predict a slight decelerated behavior at $z=0$ in agreement with diverse Dark Energy parameterizations. To test our model, we considered the corresponding curvature transition to be sufficiently small (i.e., having $\dot{\kappa}\approx0$ preserved) and defined by a smooth step-like function with a slight change between two curvature values. We implemented a MCMC Likelihood analysis using cosmic chronometers and Type Ia supernovae (local Universe observations) data in order to constraint the free parameters of the model and reconstruct $H(z)$, $q(z)$, $w_{eff}(z)$ and its comparison with the $\Lambda$CDM model. As a result, our model provides an alternative to understand the Universe acceleration without the need of a cosmological constant, obtaining the same fraction of matter density as in the traditional standard model. The behavior of the proposed model points towards a new and intriguing way to test slight violations to the cosmological principle, in particular the case of inhomogenities during low phase transitions.
Comment: 13 pages, 4 figures