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| description = TOE-E branch mapping Energy (E), Entropy (S), and Resonance (R) to black hole information stability. | | description = TOE-E branch mapping Energy (E), Entropy (S), and Resonance (R) to black hole information stability. | ||
| keywords = TOE-E, black hole, E S R, information stability | | keywords = TOE-E, black hole, E S R, information stability | ||
Revision as of 00:08, 24 August 2025
Black Hole Information Stability– TOE-E 0.0.1
Mapping E, S, R to quantum information preservation
William Birmingham; CAIPR Collective
Subjects: Physics
- TOE-E, black hole, E S R, information stability
Abstract
Access Paper:
- 📄 View PDF
- 📝 TeX Source
Paper Structure:
| Parent: | TOE-E 0.0.0 |
| Status: | Accepted(2025) |
DOI
🔖 Internal:
🌍 External:(pending)
🔖 Internal:
10.toe-e/0.0.1🌍 External:(pending)
Metadata:
| Domain: | Physics |
| Scale: | Subatomic to cosmological |
| Substrate: | Quantum fields |
| E‑type: | Hawking radiation energy flux (J/s) |
| S‑type: | Bekenstein–Hawking entropy (bits) |
| R‑type: | Quantum state coherence (0–1) |
| Timescale: | Cosmological (10^10 years) |
| Conflicts: | None declared |
| License: | CC BY 4.0 |
Citation:
APA:
William Birmingham; CAIPR Collective. (2025).
Black Hole Information Stability – TOE-E 0.0.1. TOE-E Archive.
(DOI pending)
▶ Export BibTeX
@article{TOEE-TOE-E-0.0.1},
title = { Black Hole Information Stability – TOE-E 0.0.1 },
author = { William Birmingham; CAIPR Collective },
year = { 2025 },
journal = { TOE-E Archive },
note = { DOI pending }
}
Falsifiability
If information is lost without detectable R‑mediated coherence, the model fails.
Next Steps
Simulations via quantum field theory; empirical tests via telescope data (e.g., Event Horizon Telescope).