Evolution of Dark Energies and Compact Objects in 4D Einstein Gauss Bonnet Gravity induced Universe A Data Based Perspective (2507.05223v1)

Abstract: Cosmic evolution is the most sensational topic among researchers of modern cosmology. This article explores cosmic evolution in 4D Einstein Gauss Bonnet (EGB) gravity, focusing on mass accretion of compact objects (black holes and wormholes) by dark energy (DE). Three DE models Chevallier Polarski Linder (CPL), Jassal Bagla Padmanabhan (JBP), and Barboza Alcaniz (BA) parameterizations are studied within 4D EGB gravity, with their Hubble parameters derived and compared against observational data (Cosmic Chronometers, Type Ia Supernovae, Baryon Acoustic Oscillations, and CMB). Bayesian analysis favors the CPL and BA models, with CPL providing the best fit. For black holes, mass accretion of CPL and JBP DE shows transitions between quintessence and phantom eras, while BA and LambdaCDM strictly exhibit quintessence-like behavior, driving cosmic acceleration. In contrast, wormholes exhibit the opposite trend, favoring a phantom-dominated era for the BA and LambdaCDM models. The study highlights the dynamic nature of DE in 4D EGB gravity and its role in cosmic expansion.