Finite-core Volterra reductions for a Weyl-positive Riemann phase kernel

We record a Weyl-positive reduction and certificate framework for the Riemann phase kernel associated with the even Riemann kernel $\Phi$. The manuscript does not present a complete proof of the Riemann hypothesis. Its immediate analytic target is a concrete positivity theorem for a Weyl kernel whose quantum characteristic function satisfies the Kastler--Loupias--Miracle-Sole condition in all numerical tests performed so far. Several natural factorizations are ruled out. In particular, the positive anti-Wick density route is obstructed by a local heat-deconvolution test, and several natural finite-core reductions are excluded by explicit counterexamples.
The surviving structure is a finite-core Volterra program upgraded to a closed-trace quotient certificate for the full kernel. We derive exact same-sign finite-core formulae, the second-order theta-mode identity $\phi_n(t)=(\partial_t^2-1/4)(e^{t/2}e^{-\pi n^2e^{2t}})$ for $n\ge1$, a Volterra boundary-plus-tail representation, and a quotient Schur factorization for the normalized full-$\Phi$ source/Volterra model. The latest certificate closes the active trace-range condition, the full-continuum source-inactive domination, and the Douglas/Moore--Penrose Schur hypotheses in the normalized model. What remains outside that certificate is explicitly separated: the quotient-to-original Weyl lift, uniform $\omega$-coverage for $|\omega|<1/2$, and the final bridge from Weyl/KLM positivity to the intended de Branges or RH-side formulation.