Explaining JWST star formation history at z 17 by modifying

Abstract

Recent cosmological observations indicate a 5σ discrepancy between the values of the Hubble constant H0 derived from late and early universe probes. A further possible tension at the 3σ level arises from different measurements of σ8. These measurements suggest the existence of new physics. Here, we explore several theories of modified gravity that may help to resolve these cosmological tensions. These include a family of phenomenological modified theories, where only Newton's gravitational constant and the Einstein-Boltzmann equations are affected. We consider one particular class of these theories: cosmologies with varying growth index γ and varying dark energy Equation of State (EoS) w. We also consider the normal branch of the Dvali-Gabadadze-Porrati (nDGP) model as well as k-mouflage gravity, which involves a non-trivially coupled scalar field. Our main aim is to narrow down the modified gravity landscape by constraining each model using high-redshift JWST data. Several probes are considered in this work: Stellar Mass Function (SMF), Stellar Mass Density (SMD), Star Formation Rate Density (SFRD) and Ultra-Violet Luminosity Function (UVLF) along with the Epoch of Reionization (EoR). We find that generally, the choice of rc 103.5 Mpc is preferred for nDGP, while β0.1, K0 0.9 is favored for k-mouflage. Moreover, in the context of phenomenological gravity, phantom-like dark energy EoS w -1 is preferred over the quintessence.