The cosmological constant Λ lacks a first-principles explanation; quantum field theory estimates exceed the observed value by up to 120 orders of magnitude. We show that the θ-vacuum of the Skyrme model, arising from the homotopy group π₃ (S³) = ℤ that also creates baryons as topological solitons, generates a vacuum energy density through instanton tunneling that matches the observed Λ with zero free parameters. The instanton action is the BPS topological bound S = 12π² ≈ 118. 4, yielding an exponential suppression e^ (−12π²) ≈ 10^ (−51. 4). Combined with the exact closed-form one-loop determinant over both radial and transverse fluctuations, and six symmetry-mandated zero modes (three translational, three isospin), the predicted topological susceptibility is χₜop = (1–20) × ρ_Λ (depending on semiclassical conventions), compared to the observed ρ_Λ = 3. 3 × 10⁻⁴² MeV/fm³ — agreement to within one to two orders of magnitude, with the θ-angle providing exact agreement at an O (1) value. This Λ creates a de Sitter horizon that conformally screens CMB fluctuations at the largest angular scales. The zero-parameter Ornstein–Zernike screening function S (k) = k²/ (k² + 3kdS²) reduces the Planck quadrupole anomaly from 2. 8σ tension with ΛCDM to 0. 5σ, outperforming the standard model by a factor of 4. This work was carried out through a collaboration between a human researcher (N. Hartnell) and an AI system (Claude, by Anthropic).
Nicholas Hartnell (Sun,) studied this question.