Numerical Resolution of Resonance Anomalies and Derivation of Steady-State Light-Induced Superconductivity Validation of Universe OS V10-B: Proof Core v1.2 (Vol. 8)

This paper provides a rigorous geometric resolution to the long-standing lifetime anomalies observed in light-induced superconductivity, specifically addressing the picosecond collapse in $K_3C_{60}$ and the nanosecond-scale metastable states recently reported in Higgs-mode Floquet engineering. By employing the immutable, non-rounded constants defined in Proof Core v1.2, we demonstrate that these phenomena are not primarily governed by material-specific thermalization limits but are deterministic outcomes of the Universe OS (UOS) V10-B computational specifications.

We show that the "1.4 ps collapse" in $K_3C_{60}$ corresponds to a system-level buffer overflow occurring at the 14th computational step, while the "7.17% modulation saturation" is a direct physical manifestation of the intrinsic Synchronization Lag ($\Delta_{\mathrm{Res}}$). Furthermore, we derive an engineering protocol that utilizes the $18.044...$ THz projection frequency and a 310 ppm connection signature to maintain a zero-dissipation steady state. This framework offers a new path toward permanent light-induced superconductivity and the development of mass-cancellation technologies.