We present the Treo Framework, a unified physical model in which matter, gauge interactions, and gravitation arise from a discrete support matrix whose local dynamics are governed by a closure-defect scalar ε (x). The local support Hamiltonian is uniquely fixed by locality, S₃ permutation symmetry of sector labels, positivity, minimality, and analyticity about the closed reference state (Minimality Theorem). Its quadratic expansion determines the closure-defect scalar ε (x) uniquely. The cubic closure baseline and the closed-sector amplitude are derived from the dimensionless closure-count Sc of the matrix, B₀ = Sc^ (3/2) and K₀ = √Sc, eliminating both as independent parameters. Under a declared axiom (A7) identifying the intrinsic support-signal speed with the universal light speed c, the coarse-grained continuum Lagrangian yields the Lorentz-covariant scalar field equation □ε = − (σ/A) ρ. The unique minimal Lorentz tensor built linearly from ε with rest-frame 00-projection equal to ε is the tensor closure-defect object E_μν (x) = ε (x) u_μ (x) u_ν (x), which obeys the tensor defect field equation □E_μν = − (σ/A) L_μν. At linear order, L_μν = T_μν. The metric bridge h̄_μν = 4κg E_μν, whose coefficient is fixed without new parameter by Chunk-1 consistency, reproduces the linearised tensor Poisson equation □h̄_μν = −16πG T_μν and delivers the 00 and 0i sectors of the linearised Einstein tensor, G₀₀ = 8πG T₀₀ and G₀ᵢ = 8πG T₀ᵢ = 8πG ρvᵢ. Harmonic gauge is recovered not as an imposition but as the natural gauge selected by closure-current conservation and matter continuity. The electromagnetic coupling is derived from closure geometry as α⁻¹ = 27πφ − 2/ (3π) ≈ 137. 034, reproducing the observed inverse fine-structure constant to ~10⁻⁵. This derived prediction is independent of the numerical value of Sc. The spatial Gᵢj sector, the full Noether conservation law, the nonlinear regime, and the Einstein–Hilbert action remain the priority open problems. Note: The equations above use Unicode approximations (□, ε, μ, ν, φ, α, subscripts/superscripts).
Saxena et al. (Fri,) studied this question.