A Coherence-Based Framework for Early Cosmic Organization and Large-Scale Angular Structures

Observations from the James Webb Space Telescope (JWST), the MeerKAT radio telescope, and large galaxy surveys reveal an unexpected level of early organization and large-scale coherence in cosmological structures. The presence of massive galaxies and compact objects with very high redshift, as well as evidence of coherent angular structuring within cosmic filaments, challenges scenarios based solely on late gravitational growth. This work proposes a cosmological framework based on coherence, in which large-scale organization emerges from the stochastic dynamics of a primordial field of potentialities. The formalism relies on the tools of statistical physics, including the Langevin equations, functional Fokker-Planck equations, and nucleation theory. The emergence of local coherence attractors leads to discrete condensation events, designated as flashes, which define the initial organizational conditions of the bubble universes. A weakly biased impulse during the stabilization phase naturally generates a residual angular organization of the coherence field. This organization, preserved as a low-amplitude vorticity, can be transmitted hierarchically during the formation of structures.