Essay VII derives the complete arithmetic of nothing's recursive structure — the full catalogue of stable, unstable, and non-recursive states that the helical worldline of Essay V can sustain — and the structural consequences these states generate: computational load, propagation, gravitational gradient, and the coarse-graining cascade. The essay proceeds in eight parts, building on εₛnap = 1/30 and the structural constants of Essays I through VI. Part 0 surveys Phase II's derivational status precisely. Part I derives the Dual-Route Identity T. DRI: Nₛat = 1/ (σ x δ) from both the Structural Pixel area (Route A) and the next-level grain (Route B, δ₁ = 1/σ). Part II exhaustively forecloses all Nₛat not equal to 25. Part III derives the algebraic root εₛnap = 1/ (d x n), from which the closure condition k = d × m follows, and T. KDRI: kₘin = d = 3. The even-multiplier instability is fully derived, and k=1, k=2 are foreclosed with all alternatives closed. Part IV derives the complete stable spectrum, the exhaust-per-closure identity for each stable state, sub-vacuum state analysis, and the Ω-quantum identity (spacing = dB). Part V derives computational load Ω = k and kinetic inertia in full. Part VI establishes the three-class kinetic taxonomy. Part VII derives gravity from the differential update frequency — with the wavefront minimum extent justified from T. MBD, the full deflection spectrum across all knot types, and the convergence of the deflection angle to δ/σ as k approaches infinity. Part VIII derives the coarse-graining event's most extraordinary consequence: τ₀₁ = 1 and Nₛat₁ = 1 at level 1, meaning the first coarse-grained structure saturates at its very first Chronon — a structural acceleration driving rapid condensation.
Eugene Pretorius (Fri,) studied this question.
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