Summary
Four bridges tested: DNA (bio↔chemistry), interstellar PAHs (chemistry↔astro), genetic entropy (bio↔information), and solar neutrino flux (astro↔information). Results match experimental and observational references without changing frameworks.
What is confirmed
Biology ↔ Chemistry — DNA, UV absorption near 260 nm
Canonical UV band recovered on real and synthetic sequences. Use: QC for extracts and amplicons.
Chemistry ↔ Astrophysics — Interstellar PAHs, 3.3/6.2/7.7/11.3 μm
Vibrational signatures align with astro catalogs. Use: dust mapping and ISM diagnostics.
Biology ↔ Information — Genetic entropy ≈ 2 bits/base
Stable across tested genomes. Use: anomaly detection, contamination control, edit tracking.
Astrophysics ↔ Information — Solar neutrino flux at 1 AU ≈ 6.4×10¹⁰ cm⁻²·s⁻¹
Within ≲2% of reference values. Use: cross-anchoring energy–information in solar models.
Why it matters
- One language to compare heterogeneous phenomena.
- Transferability across biology, chemistry, astrophysics, and information without ad-hoc tuning.
- Operational outputs: lab QC, spectral interpretation, information metrics.
Limits and next steps
Extreme environments and fine effects (pressure, fields, isotopes) need dedicated modules. Next: publish numeric residuals and per-point uncertainties, then open a query API by observable.