In Part I of this series, we demonstrated that the historical paradoxes of quantum measurement are naturally resolved if particles are treated as bounded, non‑linear continuous field solitons (chaoitons). Building on the CMRFp time‑symmetric measurement framework validated in multiphoton entanglement experiments, this paper provides multiple definitive nuclear confirmations of the Ouroboros+Eli model. We evaluate three competing paradigms—EWT+QCD, Pure Ouroboros, and Ouroboros+Eli—against primordial deuterium abundance (BBN), proto‑neutron star cooling (Cassiopeia A), and intrinsic redshift anomalies. The Ouroboros+Eli model achieves a 0. 24 % error on the BBN deuterium ratio, cleanly triggers the Direct Urca cascade at exactly 2. 00 ρ₀, and predicts a specific intrinsic redshift profile consistent with documented active‑galactic‑core ejections. New analyses extract the J‑field coupling constant gJ = 0. 0054 per nucleon from Sawada's data (A‑scaling confirmed to 2 %), demonstrate that a three‑layer dielectric Bragg cavity can achieve the Q ≈ 10¹⁰ required for practical J‑field detection, and validate an end‑to‑end detection pipeline integrating resonant energy injection, non‑volatile phase memory, and cross‑scale topological transport. A summary table compares all eleven empirical tests now passed by the Ouroboros program. All code and data are available at the linked repositories9, 10; we urge the reader to verify our startling conclusions by using these repositories, and widening the scope, richness and precision of our emerging new knowledge.
Paul Werbos (Sun,) studied this question.