In Lambda Convergence Universal Field Theory (LUFT), the base manifold M has dimension n as a free parameter in the Layer-0 axioms. We consolidate six independent mathematical constraints---each derived or established in companion papers---into a single funnel theorem: n = 3 is the unique positive integer satisfying all six constraints simultaneously. The constraints are: (C1) the gauge-covariant Derrick virial balance for the LUFT - system, which admits stable solitons only for n 3 (with n = 4 as the exact boundary where the gauge coefficient vanishes) ; (C2) the Lie algebra isomorphism (n) (2), required for electroweak candidate structure, which holds only for n = 3; (C3) the existence of non-trivial knots in ⁿ, required for topological confinement, which holds only for n = 3; (C4) the pre-metric Hodge constraint: the constitutive relation must map the field strength 2-form to a 1-form magnetic excitation, requiring n - 2 = 1, hence n = 3 (corroborated algebraically by the Eckmann cross-product theorem, which identifies n \3, 7\ as special, with n = 7 excluded by C1) ; (C5) the Cartan decomposition (n, ) = (n) (n) with (n, ) = n² - 1, required for color algebra dimension candidates, which matches (3) = 8 only for n = 3; (C6) observational commensurability: the --₋₎₂ gradient pair produces exactly three K-invariant local scalars on any d-manifold (by orbit counting under SO (d) ), and the unique dimension at which these observables fully resolve the local structure of M is n = 3. C6 is qualitatively distinct from C1--C5: it selects n = 3 by informational matching rather than by elimination of inconsistent alternatives. We show that the constraints, while extensionally equivalent on Z>₀ (each selects n = 3), are evidentially independent: their proofs invoke disjoint mathematical machinery (scaling analysis, Lie algebra classification, PL topology, division algebras, symmetric space theory, orbit counting in invariant theory). The convergence of six proof-independent results on a single dimension is the content of the funnel theorem. At n = 3, additional structural coincidences arise: the Cartan algebra has n² - 1 = 8 generators (matching (3) ), the shape tensor has n = 3 eigenvalues (matching the observed fermion generation count, with a traceless constraint that may constitute a prediction; see Remark rem: traceless), and the base manifold is the imaginary part of the quaternions (³ = Im (H) ), connecting LUFT to the division-algebra approach to the Standard Model. These are arithmetic consequences of n = 3, not independent constraints, but their physical significance would be substantial if the conjectural LUFT identifications are established. We explicitly mark what this argument proves and what it does not. It proves dimensional uniqueness within the LUFT framework: given the physical identification requirements (stable solitons, pre-metric EM, and Standard Model gauge candidates), the only consistent value is n = 3. It does not derive the dimension from a more primitive principle--- M = n remains a postulate, and the argument shows that n = 3 is the only value compatible with the rest of the postulates. Beyond elimination, we observe that n = 3 is not merely the last survivor but appears to occupy the role of a critical dimension: in each constraint, n = 3 sits at the boundary between structural triviality (below) and structural genericity (above). The commensurability constraint C6 goes further: it identifies n = 3 as a matching condition between field content and manifold structure, suggesting that the dimension may ultimately be derivable from informational resonance rather than assumed. Whether this can be formalized is identified as the central open problem for LUFT's foundations. Version note (v1. 7. 0, July 2026): A/B-sync with the spine v2. 13. 0 retraction: all c2 = A/B statements are replaced — A/B is a quadrature ratio with no kinematic content; the propagation cone is carried by the dispersion route (c2 = alpha*kappa at tree level, conditional on OS reconstruction). The algebraic constraints C1–C6 are unaffected.
Ilja Schots (Thu,) studied this question.