Geometric QCD III: Exact transition amplitudes and the glueball spectrum

Abstract

We complete the analysis of planar Makeenko--Migdal loop equations in the Lorentz-invariant continuum limit. Using our confining twistor-string representation, we compute the quantum fluctuation determinant, which in Minkowski space reduces to a discrete product of finite-dimensional matrix quadratures. The ζ-regularized weight is independent of winding number w. Near the mass shell, the pole singularity is generated by w ∞, suppressing fluctuation variance as 1/w. The path integral localizes on the classical trajectory, rendering the pole spectrum and transition residues parametrically exact in the large-winding WKB limit. For the open-string meson sector, we fit 40 observed states across five topological boundary sectors (h=0, 1, 2). The holonomy shift h accounts for exact geometric degeneracies between parity families, reproducing mass splittings without phenomenological spin-orbit parameters. Evaluated one-loop residues yield theoretical transition cross-sections capturing heavy-mass quenching and phase-space enhancement for high-spin light states. Applying this framework to the pure Yang--Mills closed string, we demonstrate the dynamical stability of the pure-gauge minimal surface: the conformal Liouville anomaly drives the string strictly to the trigonometric minimum (q=0). The complex elliptic geometry analytically collapses, yielding linear Regge trajectories. The translation zero-mode measure dynamically nullifies the transition amplitude of the massless scalar ghost, providing an analytic mechanism for a purely gluonic mass gap. Anchoring parameter-free glueball trajectories to the open-string tension natively recovers the exact L"uscher intercept α(0)=1/12, perfectly matching established PDG unassigned isoscalar candidates and large-Nc lattice QCD extrapolations.