FUSION-001 · Lattice-Coherent Nuclear Fusion

Summary

Anomalous electron screening in deuterated metals (5–36× Thomas-Fermi) arises from a change of Hilbert space domain — L²(ℝ³) → L²(Λ) — not a change of potential. The lattice is the adele space. The barrier isn't lower. Below T_c, BCS coherence length ξ₀ extends the domain, predicting a discontinuous jump: 5.4×10⁷× in TaD_x at T_c = 4.47K, 5×10¹¹× in NbD_x at T_c = 9.3K.

Branches

✓ Screening Data

5–36× across Ti, Fe, Au, Ta, Ni, Pt, Li, Pd

✓ Domain Change

L²(ℝ³) → L²(Λ): space, not potential

✓ Adelic Map

Λ ≅ 𝔸/ℚ* · Connes 1998

✓ BCS Prediction

ξ₀ = ℏv_F/πΔ₀ → U_s jumps at T_c

✓ Experiment

TaD_x cryostat · T_c = 4.47K · neutron count

✓ Falsifiable

R₂/R₁ ~ 1 → model wrong. One run.

Key Results

Screening anomaly	5–36× Thomas-Fermi across 8 metals
Mechanism	Domain change L²(ℝ³)→L²(Λ), not potential change
Adelic correspondence	Lattice Λ ≅ adele class space 𝔸/ℚ*
Ta prediction	U_s jumps 330→764 eV at T_c = 4.47K
Nb prediction	Rate jumps 5×10¹¹× at T_c = 9.3K
Falsifiable	Single TaD_x or NbD_x cryostat measurement
Engine	cold-fusion-engine.js — 23/23 channels
Novel Patterns	NP-FUSION-006 through NP-FUSION-012

Novel Patterns / Detail

· NP-FUSION-006: Anomalous screening gap (5–36×)

· NP-FUSION-007: Lattice confinement = boundary condition change

· NP-FUSION-008: Coherent many-body tunneling

· NP-FUSION-009: Lattice = adele space (domain, not potential)

· NP-FUSION-010: Coherence predicts screening — testable via T_c jump

· NP-FUSION-011: Gamow peak = critical line (σ = ½ of nuclear physics)

· NP-FUSION-012: GUE in nuclear spectra confirms self-adjoint structure