Non-Riemannian Unified Field Theory: A Dissertation on Informational Cosmogenesis

Abstract: This work introduces an exploratory, high-level conceptual framework within theoretical physics, proposing a non-Riemannian approach to extended field structures and the mechanics of informational cosmogenesis. By moving beyond traditional four-dimensional constraints, the model investigates a complex-valued spacetime formulation (n-dimensional manifolds) and the potential interactions between spacetime curvature, vacuum vorticity, and relativistic momentum within extreme gravitational regimes. Central to this study is the "Anas-Gabas Survival Criterion, " a novel postulate exploring how relativistic momentum acts as a structural "stiffening" agent against tidal disruption near singularities. The framework analyzes the response of matter and information at the event horizon, proposing a mechanism for information preservation and the potential transition of mass-energy into a "Child Universe" via a spacetime vortex bridge. Future Research Directions & Extensions: This initial version (v1. 0) serves as a foundational roadmap for several key areas of future inquiry: 1. Momentum Redistribution Hypothesis: Future iterations will focus on the non-linear redistribution of momentum within the Structural Rigidity Tensor (Q_μν) to determine if specific energy-density thresholds can prevent the formation of a physical singularity. 2. Wormhole Stability & Topology: We intend to explore the broader cosmological implications of our framework concerning the stability of traversable wormhole-like geometries, specifically investigating if vacuum vorticity can provide the necessary exotic-stress-energy equivalent required for throat stabilization. 3. The H0 Discrepancy (Hubble Tension): A major upcoming project involves applying the VIFT-SVG (Vortex-Induced Field Theory) to the early universe to determine if "Torsional Friction" in the early expansion phase can reconcile the current discrepancy between CMB measurements and local distance ladder observations. 4. Quantum-Classical Bridge: Future work will seek to map the complex-valued spacetime manifold onto existing Quantum Field Theory (QFT) operators to see if the "Anas Limit" (8. 12M⊙) correlates with specific quantum degeneracy pressures. 5. Computational Simulations: We aim to develop numerical relativity simulations based on the Einstein-Anas Field Equations (EAFE) to visualize the evolution of the ergosphere during the proposed "Vortex Transition. " This study is an early-stage theoretical exploration. It is released to the scientific community as a basis for further mathematical refinement, collaborative critique, and cross-disciplinary research into the nature of gravity and the origin of the cosmos. Keywords: Theoretical Physics, Modified Gravity, Non-Riemannian Geometry, Einstein-Anas Field Equations, EAFE, Anas-Gabas Criterion, Spacetime Vortex, Hubble Tension, Information Paradox, Black Hole Physics, Cosmogenesis, Complex-Valued Manifolds, SVG-VIFT Framework.