This work introduces a unified operational framework for understanding superconductivity, mass, confinement, and horizons through a single dimensionless parameter: the boundary–sealing index β. By decomposing physical correlation as C = Cₑxt + Cₛeal and defining β = Qc / Qᵢ (where Qᵢ is the internal correlation lifetime and Qc the boundary leakage lifetime), this paper shows that phenomena traditionally treated as unrelated — Meissner expulsion, quark confinement, Higgs mass generation, and black-hole horizons — all arise from the same physical structure: suppression of correlation leakage across boundaries. Unlike purely interpretive or analogical approaches, β is directly tied to measurable quantities: penetration depth, phase stiffness, microwave loss, interlayer coupling, and dissipation rates. This allows the framework to be used not only to reinterpret fundamental physics, but also to guide materials design. Applying this structure to moiré systems, twisted bilayer graphene, and three-dimensional graphene lattices, the paper derives quantitative conditions under which 300–500 K correlation-sealed phases become physically achievable. These states are not proposed as power-transmission superconductors, but as quantum-coherent, phase-stable materials that act as artificial horizons — enabling quantum circuits, memories, and communication nodes to operate without cryogenic cooling. The theory is explicitly falsifiable through: • β (T) scaling across materials, • interface-controlled leakage experiments, • microwave and transport loss vs Tc, • and engineered interlayer coupling. If correct, this framework unifies mass, force, matter, and quantum materials as different phases of the same underlying correlation-sealing physics.
Koji Mochizuki (Tue,) studied this question.