This specification presents a unified architectural framework for an autonomous Low Earth Orbit (LEO) bio-quantum payload designed to enable leapfrog space-ground telecommunications. The architecture integrates three tightly coupled layers: (1) unitary quantum-to-bio state transduction using ternary xeno-nucleic acid (TNA/PNA) matrices, (2) multi-scale Landauer thermodynamic management through 6D hyper-chaotic routing governed by the Neural-Plasma Audit Protocol (NPAP) and Extanton swarm dynamics, and (3) active physical-layer radiation protection via a magnetized dusty plasma shield driven by high-order Orbital Angular Momentum (OAM) modes. By treating quantum information integrity, entropic dissipation, and cosmic ray shielding as a single closed-loop thermodynamic system, the design achieves structural resilience and computational stability under galactic cosmic ray exposure without relying on conventional passive mass shielding. The framework is particularly suited for future CubeSat and cislunar missions requiring high-throughput, radiation-hardened quantum-classical hybrid processing and long-term molecular information storage. This work synthesizes concepts from quantum teleportation routing, non-binary information thermodynamics, dusty plasma physics, and lead-free piezoelectric materials into a coherent, deployable payload architecture.
Venerable et al. (Fri,) studied this question.
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