Dark energy, spatial curvature, and star formation efficiency from JWST photometric and spectroscopic high-redshift galaxies

Abstract

Early observations from the James Webb Space Telescope (JWST) have revealed an overabundance of massive high-redshift galaxies, raising the question of whether this points to new physics beyond , or an enhanced formation efficiency of massive stars. We revisit this issue going beyond earlier analyses based on direct comparisons to theoretical bounds at a fixed cosmology, by performing a full Bayesian analysis of the most extreme galaxies in the CEERS imaging and FRESCO spectroscopic samples, jointly constraining cosmological parameters and the baryon-to-star conversion efficiency ε. We do so not only within the spatially flat model, but also in models where the dark energy equation of state w and/or the spatial curvature parameter K are allowed to vary, carefully discussing the impact of both w and K on the cumulative comoving stellar mass density. Within the flat model, once cosmological parameters are marginalized over, the CEERS sample provides a weak 2σ lower limit of ε 0.07, compatible with astrophysical expectations. In contrast, the FRESCO sample requires ε 0.5 at 2σ, with values ε 0.2 disfavored at >5σ. These results do not qualitatively change when we allow w and/or K to vary, with no evidence for deviations from w=-1 or K=0. Our results therefore suggest that the origin of the ``JWST tension'' is unlikely to be cosmological, but lies in the astrophysics of galaxy formation.