This paper develops a geometric stability framework for the zeta dynamics based on four independent operators: thermodynamic equilibrium Θ, curvature-neutrality K, informational symmetry I, and torsional cancellation T. Each operator suppresses a distinct local instability of log|ζ(s)| or arg ζ(s). Under the hypothesis that their gradients are linearly independent at common zeros, the simultaneous neutralization of all four imposes a codimension–four constraint system in a two-dimensional analytic domain, forcing collapse onto a one-dimensional rigidity manifold. We prove that this rigidity spine coincides with the critical line Re(s) = 1/2, providing a conceptual stability explanation for its privileged role in the zeta geometry. The paper includes diagrammatic representations of curvature-neutrality geometry, torsional-tightening flow diagrams, the global rigidity spine, open-endpoint structures illustrating meta-rigidity, and parallel-branch incompleteness models. This work offers a structural perspective on how geometric, informational, and torsional stabilizations enforce collapse onto the critical line and provides a diagrammatically reinforced conceptual stability theory for the Riemann zeta dynamics.
Bailey William (Fri,) studied this question.