The Role of Spacetime Torsion and Primordial Energy Fields in Early Universe Structure Formation: A CEIT Framework for JWST Observations of High Redshift Galaxies and Primordial Black Holes

The standard ΛCDM cosmological model faces profound challenges in explaining the rapid emergence of high-redshift structures observed by the James Webb Space Telescope (JWST), including massive galaxies and supermassive black holes at z > 10. We present a theoretical framework based on the Cosmic Energy Inversion Theory (CEIT), which posits that gravitational dynamics are driven by spacetime torsion, dynamically sourced by gradients of a primordial energy field ℰ(x,t). This theory naturally replaces the dark matter paradigm with geometric pressure and explains cosmic acceleration through field decay. Within this framework, we demonstrate that elevated ambient ℰ fields in the early universe catalysed accelerated baryonic structure formation by reducing particle stability timescales. Furthermore, torsion-enhanced dynamo action and a modified Blandford-Znajek mechanism efficiently generated ordered magnetic fields and powered compact jets, facilitating the rapid growth of primordial black holes. Our model quantitatively reproduces the stellar masses, formation timescales, and magnetic field coherence lengths of the earliest observed systems, offering a unified solution to the twin puzzles of rapid galaxy and black hole formation without invoking exotic dark matter components or fine-tuned initial conditions.