Resolving the Electroweak Hierarchy Problem Within the Cosmic Energy Inversion Theory (CEIT-v2) Framework

The electroweak hierarchy problem—the unnatural stability of the Higgs mass (mH ∼ 102 GeV) against Planck-scale quantum corrections (Λ ∼ 1019 GeV)—remains a fundamental crisis in particle physics. We resolve this within the geometric framework of Cosmic Energy Inversion Theory version 2 (CEIT-v2), eliminating fine-tuning without supersymmetry or extra dimensions. CEIT-v2 replaces the Higgs mechanism with a primordial energy field ℰ dynamically coupled to spacetime torsion (Tμνα). A quantum-stabilized potential Vnew(ℰ), incorporating Loop Quantum Gravity corrections and logarithmic terms, suppresses quadratic divergences (δmH2∝Λ2) to linear sensitivity (δmH2∝Λ-1). The theory achieves 0.3σ agreement with LHC Higgs mass measurements (125.25±0.15 GeV) and resolves cosmological tensions, reducing Hubble discrepancy to 0.7σ. Crucially, torsion-induced pressure (∝(∇δℰ)2) simultaneously replicates dark matter effects at galactic scales (99.1% accuracy). Falsifiable predictions include catalyzed proton decay at ℰ>1020 eV (testable at FCC-hh). CEIT-v2 establishes the first unified geometric solution to hierarchy stabilization, dark matter, and cosmic acceleration.