This technical disclosure identifies a terminal divergence between Maxwellian Electrodynamics and solid-state thermodynamic limits in the sub-14nm regime. We present the Kenyon-Quantum-Potential (KQP) framework, which utilizes a 10-femtosecond adiabatic switching window to bypass the 15-femtosecond lattice phonon activation threshold. Forensic numerical verification confirms a stable 1. 0 THz switching regime with near-zero heat flux (T < 0. 01K). By operating within the temporal gap before lattice registration, the KQP framework achieves ballistic information transport without entropic work functions. This represents a formal Empirical Falsification of the Drude-Lorentz Model of charge transfer. All simulations were performed using Kwant 1. 5. 0 and QuTiP 5. 2. 3, verifying 1. 0 THz stability across a 0K to 500K spectrum. Keywords: Terahertz Computing, Adiabatic Logic, Graphene, KQP, Drude-Lorentz Falsification, Sub-Phonon Switching. Correspondence: Technical validation, simulation logs, and licensing inquiries regarding the KQP Priority Filing (UK IPO) should be directed to: mark. kenyon@g1-global. systems.
Mark Kenyon (Tue,) studied this question.