This paper explores the geometric and asymptotic anatomy of the unrestricted partition space P (n), resolving its asymptotic equidistribution failure through a precise subdivision of the partition simplex. We identify lower-dimensional geometry as the primary source of cyclotomic noise and structural instability. To isolate the pure spectral resonance of the system, we establish the logical and topological necessity of the restricted subspace P>₊ (n) and apply the Kaleidoscopic Filter Theorem. By utilizing the coefficients of k-dimensional Weyl reflections on the infinite sequence of unrestricted partitions p (n), we exactly annihilate all lower-dimensional geometry. The result of this convolution strictly evaluates the number of partitions of n formed exclusively by components strictly greater than k. Ultimately, we demonstrate that the conformal mapping of the spectrum of the resulting combinatorial covariance operator rigidly constrains the roots of the Riemann Zeta function to the critical line (s) = 1/2. By formalizing the trace-class rigidity and unitary isometry of the continuum limit, we establish a direct isomorphism between the Fredholm determinant of the filtered spatial operator and the Hadamard factorization of the Riemann -function, yielding a direct spectral realization of the Riemann Hypothesis via de Branges Reproducing Kernel spaces.
Antonio Bonelli (Sat,) studied this question.