The Impact of Early Massive Galaxy Formation on the Cosmic Microwave Background
Eda Gjergo, Pavel Kroupa
arXiv:2505.04687v1 Announce Type: new
Abstract: The Cosmic Microwave Background (CMB) anisotropies, corrected for foreground effects, form the foundation of cosmology and support the Big Bang model. A previously overlooked foreground component is the formation of massive early-type galaxies (ETGs), which can no longer be ignored, particularly in light of JWST’s detection of massive, evolved systems at extreme redshifts (z > 13). The rapid formation of massive ETGs has been advocated in galaxy evolution studies for decades, and recent evidence has compelled even proponents of hierarchical mass assembly to acknowledge the fact that massive ETGs evolve quickly. Constraints from chemical evolution are particularly stringent. Without both intense star formation and a top-heavy galaxy-wide initial mass function of stars (IMF), it is difficult to reconcile stellar population synthesis models with the high metallicity and abundance patterns of alpha elements. We infer from previous studies that the progenitor cloud of each massive ETG must have had a radius of approximately 400 kpc. Comparing this value to the average present-day separation of massive ETGs, their formation may have occurred around 15 arXiv:2505.04687v1 Announce Type: new
Abstract: The Cosmic Microwave Background (CMB) anisotropies, corrected for foreground effects, form the foundation of cosmology and support the Big Bang model. A previously overlooked foreground component is the formation of massive early-type galaxies (ETGs), which can no longer be ignored, particularly in light of JWST’s detection of massive, evolved systems at extreme redshifts (z > 13). The rapid formation of massive ETGs has been advocated in galaxy evolution studies for decades, and recent evidence has compelled even proponents of hierarchical mass assembly to acknowledge the fact that massive ETGs evolve quickly. Constraints from chemical evolution are particularly stringent. Without both intense star formation and a top-heavy galaxy-wide initial mass function of stars (IMF), it is difficult to reconcile stellar population synthesis models with the high metallicity and abundance patterns of alpha elements. We infer from previous studies that the progenitor cloud of each massive ETG must have had a radius of approximately 400 kpc. Comparing this value to the average present-day separation of massive ETGs, their formation may have occurred around 15