This thesis establishes a definitive analytical proof of the Riemann Hypothesis and its generalized extensions by demonstrating the absolute spectral confinement of non-trivial zeros within a globally rigid Frechet configuration space. Moving beyond classical complex function theory, the framework constructs a novel adelic spectral rigidity operator over the ring of adeles, translating the location of zeros into the determination of stable resonant states. To overcome the historic challenge of spectral leakage that invalidated previous physics-based approaches, we introduce an autonomous monodromy filter that achieves a clean, unconditional decoupling of the discrete spectrum from the continuous background. Central to the proof is a non-linear geometric deformation flow governed by a flat gauge connection, which establishes that any hypothetical off-axis migration from the critical line generates an unsustainable, divergent topological tension in the idelic module. By formalizing a global Fredholm determinant modified under a novel regularization identity, this work proves that the critical axis operates as a mandatory topological attractor maximizing arithmetic entropy. The result delivers an entirely non-circular, structurally cohesive architecture where the horizontal stability of the zeros emerges as an inevitable consequence of the internal rigidity of the global field, successfully closing the historic problem.
Jean Carlos Vivar Benítez (Wed,) studied this question.