Thermodynamic Holographic Entanglement Theory

The Thermodynamic Holographic Entanglement Theory (T-HET) presents a comprehensive framework where spacetime, matter, forces, and interactions emerge from the dynamics of a scalar field representing local entanglement entropy, defined over a cohesive topological substrate. Departing from traditional models that assume geometry or quantized fields as foundational, T-HET posits that physical laws originate from structured informational flow governed by logical coherence. The theory introduces a variational principle and a self-interaction potential that guides the evolution of this entropic field. From it, a bivector structure emerges that encodes the geometry and causality of spacetime, without presupposing a pre-existing manifold.

T-HET formulates 21 fundamental laws that unify causality, decoherence, topological transitions, subsystem embedding, and emergent classicality. Using this structure, the theory addresses 81 major unresolved problems in physics, including the nature of time’s arrow, the origin of mass and particle generations, CP violation, the information paradox in black holes, and the emergence of classical behavior from quantum systems.

In cosmology, the theory replaces the singularity of the classical Big Bang with a smooth initial phase driven by entropic gradients, compatible with gravitational theorems such as those of Penrose and Hawking. This phase transition gives rise to inflation, and the theory naturally explains the cosmological constant, the origin of dark energy, and observed anisotropies in the cosmic microwave background. Dark matter is interpreted as localized, non-radiative structures of the entropic field, while vacuum energy arises from stable minima in the entropic potential landscape.

T-HET makes empirical predictions that distinguish it from conventional models. These include the presence of gravitational wave echoes resulting from entropic horizons, signatures of new particle-like excitations near the electroweak scale, and specific non-Gaussian features in cosmic background measurements. All these predictions have been tested against real observational datasets from LIGO, CMS, and Planck using robust statistical criteria such as chi-square, AIC, BIC, and Bayesian model selection.

Theoretically, T-HET draws from and extends insights in quantum information theory, category theory, holography, and modal logic. It suggests that physical laws are not absolute but are emergent attractors within a larger informational configuration space. The quantization of the entropic field yields consistent dynamical equations, propagators, and feedback with classical geometry, enabling a new synthesis between thermodynamics, gravity, and quantum theory.

In sum, T-HET offers a mathematically consistent and observationally grounded approach to unifying the known forces of nature. It reframes our understanding of reality as a structured entropic manifold governed by coherence, topology, and the dynamics of information itself.