Rabbit Holes and Exploratory Paths
🧪 1. Abandoned Theoretical Constructs
- Symmetric sinertia wells — explored as an alternative to single-sourced scalar collapse, but led to field instabilities.
- Double-well scalar potential — introduced resonance artifacts not observed in hydrogen spectrum.
- Particles move at the speed of light in the a sinertia 100% depleted zone — Explored the concept of once a kenos state is encounter (no available sinertia for coupling), a black hole existed. Without coupling the particles could move at the speed of light. Abandoned for several reasons.
🧠2. Paths That Almost Worked
- Anti-resonance photon coupling — came close to matching observed transitions, but introduced an unphysical wavelength drift.
- Time-asymmetric saturation — provided one-sided collapse behavior, but violated scalar coherence when reversed.
🧬 3. Unresolved or Open Questions
- How scalar coherence enforces quantization at relativistic energies?
- What governs the transition from stable sinertia flux to scalar saturation near black holes?
- Connection between photon wavelength and hydrogen ground state.
🌀 4. Crossroads with Other Frameworks
- Attempted unification with tensor-based GR — rejected to preserve NUVO’s scalar geometry independence.
- Gauge field reinterpretations — produced partial analogs but broke frame-constrained closure.
💠5. Philosophical and Foundational Speculations
- Is rest mass a derived quantity from scalar flux geometry?
- Could scalar coherence encode information theory directly?
🧠Closing Note
The NUVO Rabbit Holes serve both as a record of scientific process and as inspiration for future exploration. These side paths, while sometimes unfruitful, demonstrate the depth and creativity behind the theory — and may yet contain seeds of new insights.