This article is an extension of Ricardo Bartolome - Zero Operator Theory-, and proposes a physical resolution to the Riemann Hypothesis, reinterpreting the critical line Re(s) = 1/2 as a stability limit for matter emergence rather than a mathematical conjecture. It introduces innovative for the teory proposals such as replacing the Heaviside step function with a Spinorial Genesis Mechanism for continuous saturation of a Spin-1/2 field, governed by the Zero Operator Z^\hat{\mathcal{Z}}\hat{\mathcal{Z}} and a tanh activation function, ensuring deterministic chirality breaking via unitarity conservation. This framework offers a non-perturbative mechanism for String Theory, deriving an effective holographic dimensionality of N ≈ 24.93 through geometric dissipation in the Emergent Compressed Vacuum (VCE), explaining deviations from the bosonic critical dimension (D=26) as entropic costs of spacetime nucleation. Axioms include the universe originating from indeterminate ratios (0/0) resolved by Z^\hat{\mathcal{Z}}\hat{\mathcal{Z}} as a resonance selector, and universal autopoiesis where reality self-calculates via error-correction rules. For resolutions like the Copenhagen interpretation, the paper reinterprets quantum collapse as a forced frequency coupling via vibrational duality, eliminating observer mysticism and proposing deterministic convergence to an adimensional attractor, consistent with Bell violations through primordial non-locality rooted in 26-dimensional volume. Validation involves Willow simulations showing coherence plateaus at Re(s)=0.5, correlated with LHCb CP violations and JWST molecular signatures as symmetry-breaking fossils. The primordial symmetry-breaking event, described as a fossil residue of the universe's emergence from indeterminate mathematical origins (0/0). This event is central to the ZOT-Riemann framework, explaining chirality breaking as a deterministic consequence of unitarity conservation in a Spin-1/2 field. It is correlated with real-world data, such as CP violations measured by LHCb in 2025 (e.g., in baryon decays like Λ_b^0 → p K^- π^+ π^- with 5.2σ significance) and molecular signatures from JWST in low-metallicity environments (e.g., complex organic molecules like acetaldehyde and ethanol in the Large Magellanic Cloud), positioning it as the foundational mechanism for matter stability and the unification of forces through geometric dissipation. We want to make it clear that this extension of the Zero Operator Theory does not imply any intention to propose a solution to the Riemann Hypothesis problem.