🌀 Phase-Pi-Quantum-Prior Topological Superselection Z/6Z: Analytical Phase Derivation and Dissipative Stabilization for FTQC Cryptanalysis The analytic core of the Z/6Z topological superselection. The perfect geometric duality between the resonant channels (blue and red) demonstrates the Zero-Leakage adaptive strategy driven by the exact holonomic phase shift Δϕ=π.* 🎯 TL;DR – The Essentials 🔬 Theoretical Breakthroughs 📐 Analytical Phase Discovery: Proof that the optimal initialization phases (ϕ1,ϕ2) are not heuristic. ϕ2=π emerges from the unit group isomorphism (Z/6Z)×≅Z/2Z acting as a non-commutative Berry Holonomy. 🔄 Renormalization Group (RG) Origin: The thermodynamic phase ϕ1≈Rfund/10 is strictly derived as an infrared fixed point of the Callan-Symanzik beta function, coupled to the Euler-Kronecker invariant. ⚡ Polynomial Complexity: Exact state preparation via Matrix Product States (MPS) with constant topological bond dimension χ≤6, avoiding the exponential O(2n) overhead of arbitrary distributions. 🛡️ Parent Lindbladian it is the geometric penalty for trying to squeeze the continuous vacuum into a discrete binary register." This work establishes that arithmetic is not a random sequence, but a deterministic wave structure encoded in the Z/6Z topology. Recognizing this allows us to fundamentally rewrite the rules of quantum cryptanalysis and hardware initialization for the FTQC era. Last Update: May, 2026 | Status: Under Review at Journal of Physics A: Mathematical and Theoretical JPhysA-124899 | Built with ⚛️, 🐍 & 🛡️ Lean 4
José Ignacio Peinador Sala (Tue,) studied this question.