C. M. Winckler, P. P. Avelino, L. Sousa
Abstract
Discrete symmetry-breaking phase transitions in the early Universe may have caused the formation of networks of sheet-like topological defects, usually referred to as domain walls, which separate regions that have settled into different vacuum states. Field theory simulations predict the successive collapse of increasingly larger domains, which could potentially leave observable imprints in present-day large-scale structures. We use a nonparametric analytical model to provide an estimate of the final decay energy of these walls and their associated collapse rate, as a function of redshift. The energy released by collapsing walls can act as a seed for density perturbations in the background matter field, influencing structure formation. We estimate the dependence of the current mass of the resulting nonlinear objects on the collapse redshift and wall tension, showing that domain walls can contribute to the formation of objects as massive as present-day galaxy clusters. Still, we confirm that the contribution of standard domain walls to structure formation is subdominant. In contrast, biased domain walls—originating in models with an approximate (or biased) discrete symmetry breaking—generally face much less stringent constraints on their tension, which allows for significantly higher collapse energies. Based on our analysis, we are able to show that the collapse of such biased wall networks can provide a significant contribution to structure formation, and in particular, a mass excess at z≳7, as suggested by JWST data.
Keywords
Cosmology / Cosmology and Nongalactic Astrophysics
Physical Review D
Volume 112, Issue 123506
2025 December
