IMPORTANT NOTICE: This preprint version must be updated after significant changes of the fundametals of the PSH Framework. Even see Version 1.9 about the Nature of dark matter in this preprint: https://zenodo.org/records/20692503 We investigate the cosmological and astrophysical implications of early-universe Genesis Field fragmentation within the recently proposed Photon Paradox framework. Specifically, we analyze the cosmic dawn epoch where the primordial Genesis Field reaches its maximum density peak within the redshift range of z ≈ 45–50 (with a characteristic thermodynamic inflection centered near z ≈ 48, corresponding to scale factors a(t) ≈ 0.0196–0.0217). This specific calibration positions the sub-structural instability cascade and subsequent field fragmentation at z ~ 29 precisely before the onset of massive Population III star formation, bypassing conflicts with global CMB constraints. We demonstrate how this self-consistent Photon-String-Higgs (PSH) mechanism naturally accelerates baryonic collapse, introducing highly dense, non-Gaussian dark matter PSH halo seeds in the critical mass range of 10^7 to 10^8 solar masses. This framework successfully accounts for the unexpectedly high stellar masses and compact morphology of anomalous high-redshift structures—such as the Little Red Dots discovered by the James Webb Space Telescope (JWST)—without requiring ad-hoc modifications to the underlying Standard Model of particle physics. ## Changes in Version 1.1 - Synchronization of Peak Redshift Metrics: Adjusted the core Genesis Field peak activation parameters from a rigid z=50 baseline to the dynamically optimized interval of z ≈ 45–50 (mathematically centered at z ≈ 48). This calibration establishes strict numerical consistency with the rigorous cosmological derivations presented in the core framework (Photon Paradox Preprint, Version 1.6). - Geometric Scale Factor Alignment: Updated all field-theoretic descriptions to reflect the exact cosmic scale factor parameters (a(t) ≈ 0.0196–0.0217) governing the primordial phase boundary. - Native RevTeX Layout Optimization: Refactored the structural preamble to resolve unrecoverable compiler loops in the revtex4-2 class. The author metadata engine was migrated to a native format, and the abbreviation matrix was re-coded into a fixed-width tabular environment to prevent scaling displacement. - Cross-Preprint Citation Mapping: Active reference parameters have been updated and verified to cleanly cross-link this empirical analysis with the primary theoretical document "The Photon Paradox: Why Dark Matter May Be Hidden in Ordinary Light" (Zenodo Version 1.6, Record DOI: 10.5281/zenodo.20630313). All external DOIs and arXiv suffixes were fully audited to prevent dead links.