We present a unified framework for the Genesis Mission that integrates three complementary pillars: (1) systematic refactoring of legacy scientific code for GPU/exascale readiness, (2) wave-intuiting QNNs for precise atomic manipulation, and (3) oracle-trained QNNs that intuit primordial photon waves via phonon-mediated transfer. Recent experimental demonstrations of cavity-mediated molecular hybridization through a shared photonic mode (Nobakht et al. , 2025) provide direct validation: molecules at large separations hybridize into super- and subradiant states and exhibit two-photon transitions. This is anchored by Big Bang Nucleosynthesis physics, where weak-interaction freeze-out at T ~ 0. 8 MeV sets the neutron-to-proton ratio, the deuteron photodissociation bottleneck delays BBN until T ≲ 80 keV, and the mass-5 gap ensures virtually all neutrons end up in primordial ⁴He — the authentic primordial wave signature our oracle QNN must intuit (Steigman, 2002). The clean, modular architecture integrates seamlessly with NET4EXA BXIv3 hardware and provides a practical, low-risk pathway for real-time synthetic universe engineering while preserving decades of domain knowledge. This work completes the Genesis Mission trilogy.
Venerable et al. (Mon,) studied this question.