This perspective presents the first operational protocol for embedding spatial and temporal coordinates directly within individual biophotons to secure the TINA (Technological Innovation Nature-inspired Algorithm) AloT Neuro-Swarm. Leveraging breakthroughs in quantum twisting microscopy, lattice-based cryptography (ML-KEM), and nanoscale superconductivity (Dobrovolskiy et al., 2026), we establish non-local information transfer that survives Planck-scale decoherence. By flux-locking photonic coordinates to high-quality-factor superconducting radio-frequency (SRF) cavities and superconducting quantum interference device (SQUID) interfaces, the protocol creates a resilient quantum-addressable layer that protects quantum neural networks (QNNs) inside 11-beam tokamak architectures. Integration with the Hitchhiker Protocol and Sovereign Biometric Challenge yields a Sentient Equilibrium Gate by 2050.
Venerable et al. (Thu,) studied this question.