A Calibration-Free Fixed Point of Curved Boolean Logic Matching the Fine-Structure Constant

We show that Curved Boolean Logic (CBL) admits a calibration-free fixed point at which the per-face holonomy theta_0 is the same across independent minimal faces (CHSH, KCBS, SAT_6). Equality is enforced by solving the two-component system F(delta, gamma_4, gamma_5, gamma_6) = (theta_0^(4) - theta_0^(5), theta_0^(5) - theta_0^(6)) = 0 with a Gauss-Newton method (no external scale). A finite-difference Jacobian is full rank at the solution, implying local uniqueness. Working at the coupling level g = |theta_0|/(2*pi*n) removes hidden length factors; at the equality point our normalization audit shows g = alpha (Thomson limit) within numerical tolerance. The SU(1,1) corner words and overlap placements used to compute theta_0 are specified exactly; we also report a variational minimax analysis on g and a pilot non-backtracking spectral density that coincides numerically with the per-edge coupling, suggesting a purely topological formulation. Scope: the match is to the low-energy (Thomson) limit; a full spectral equality on the contextual complex is left as a short conjecture. These results promote the CBL--alpha connection from a calibrated identification to a calibration-free derivation candidate.