Probing Reionization-Era Galaxies with JWST UV Luminosity Functions and Large-Scale Clustering

Abstract: The James Webb Space Telescope (JWST) has transformed our understanding of early galaxy formation, providing an unprecedented view of the first billion years of cosmic history. These observations offer a crucial opportunity to probe the interplay between galaxy formation and reionization, placing stringent constraints on theoretical models. In this work, we build upon our previously developed semi-analytical framework that self-consistently models the evolving UV luminosity function (UVLF) of galaxies and the global reionization history while incorporating the effects of radiative feedback. Comparing our predictions with JWST and HST data, we identify a fundamental tension: models that match the UVLF fail to reproduce the observed evolution of galaxy clustering (bias) with redshift, and vice versa. To resolve this, we introduce a mass-dependent duty cycle linked to star formation duration. This duty cycle approaches unity at $z > 11$, requiring either enhanced UV radiation production or increased star formation efficiency to match the JWST UVLFs, while declining towards lower redshifts ($5 < z \leq 9$) to remain consistent with the bias measurements. Reconciling theory with observations requires that the characteristic star formation timescale increases from $\approx 80$ Myr at $z \approx 6$ to $\approx 120$ Myr at $z \approx 8$. Finally, our extended model, assuming a halo mass-independent escape fraction of $\approx 12\%$, produces a reionization history consistent with current constraints. These findings underscore the importance of jointly constraining high-redshift galaxy models using both UVLF and bias statistics to accurately interpret JWST data and refine our understanding of early cosmic evolution.