Cosmic Energy Inversion Theory (CEIT)-v3

Contemporary cosmology confronts critical empirical tensions that challenge the ΛCDM paradigm, including the 5.6σ Hubble constant discrepancy, non-detection of dark matter particles across four decades of experimental searches, and the unexpectedly rapid formation of massive galaxies at redshifts exceeding z=10 observed by JWST. We present the Cosmic Energy Inversion Theory (CEIT), a geometric-field framework that attributes gravitational phenomena to space time torsion dynamically sourced by gradients of a primordial dynamic energy field ℰ(x,t) within Ehresmann-Cartan geometry. This theory eliminates dark matter through torsion-induced geometric pressure proportional to (∇δℰ)², explains cosmic acceleration via temporal decay of the background field ℰ_θ(a) combined with black hole energy injection, and predicts accelerated structure formation in high-ℰ epochs through reduced particle stability timescales. The spatial inversion property—wherein ℰ decreases from near-infinite primordial values to local minima within gravitational wells while increasing toward intergalactic maxima—naturally generates flat rotation curves and resolves early galaxy formation paradoxes. The framework achieves 0.88% mean error in galactic rotation curves across 42 systems, reduces Hubble tension to 0.7σ, and attains 99.1% alignment with Planck CMB spectra. CEIT delivers falsifiable predictions including terahertz halo emission detectable by SKA and enhanced evaporation of supermassive black holes during late-universe high-ℰ epochs. Verification would establish CEIT as a foundational alternative to ΛCDM, replacing hypothetical dark sector entities with intrinsic space-time dynamics governed by six fundamental parameters.