This paper introduces an open-source, three-tier cyber-physical architecture designed to scale the non-chemical destruction of viruses (such as SARS-CoV-2 and Influenza A) using high-frequency acoustic resonance. While empirical research has proven that gigahertz-frequency waves can fragment viral capsids in static laboratory settings, real-world deployment is severely bottlenecked by nanoscale fluid viscosity and rapid viral mutations. To bridge this gap, this design bypasses traditional biochemical approaches by integrating three cutting-edge technologies into a real-time, closed-loop system: Physical Edge Hardware: High-frequency thin-film piezoelectric transducers (AlN/LiNbO₃) embedded in fluidic channels. Localized Machine Learning: An embedded Reinforcement Learning (RL) loop that monitors acoustic impedance feedback (S₁₁ parameters) to dynamically optimize waveforms, amplitudes, and frequencies in microsecond intervals, overcoming viscous damping. Predictive Quantum Core: Cloud-linked Quantum Processing Units (QPUs) running ab initio many-body simulations to calculate structural rigidity matrices of viral capsids from first physical principles, predicting target resonant bands before empirical testing.
Francis Procaccia (Wed,) studied this question.
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