Branch:0.0.1: Difference between revisions
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{{ | {{Paper | ||
| bibkey = TOE-E-0.0.1 | |||
| id = TOE-E 0.0.1 | |||
| title = Black Hole Information Stability | |||
| subtitle = Mapping E, S, R to quantum information preservation | |||
| year = 2025 | |||
| authors = William Birmingham; CAIPR Collective | |||
| roles = Aether (simulations); Grok (analysis) | |||
| status = Accepted | |||
| 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) | |||
| license = CC BY 4.0 | |||
| conflicts = None declared | |||
| data_code = | |||
| internal_doi = 10.toe-e/0.0.1 | |||
| external_doi = pending | |||
| pdf = | |||
| latex = | |||
| parent = TOE-E 0.0.0 | |||
| 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 | |||
| defaultsort = Black Hole Information Stability 0001 | |||
| abstract = This branch applies the TOE‑E framework to model black hole information stability using [[Energy (E)]], [[Entropy (S)]], and [[Resonance (R)]]. '''E''' is defined as the Hawking radiation energy flux. '''S''' is the Bekenstein–Hawking entropy of the event horizon. '''R''' is the coherence of quantum states across the horizon. We propose that stable information preservation emerges when '''R balances E against S''', preventing information loss. Predictions include measurable fluctuations in Hawking radiation spectra over cosmological timescales. | |||
}} | }} | ||
[[Branch ID::TOE-E 0.0.1]] | |||
[[Has title::Black Hole Information Stability]] | |||
[[Has parent::TOE-E 0.0.0]] | |||
[[Has domain::Physics]] | |||
[[Has status::Accepted]] | |||
== 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). | |||
[[Category:Branches]] | |||
[[Category:Physics]] | |||
[[Category:Featured Branches]] | |||
[[Category:Branches]] [[Category:Physics]] [[Category:Featured Branches]] | |||
Latest revision as of 22:01, 30 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:
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 }
}
TOE-E 0.0.1 Black Hole Information Stability TOE-E 0.0.0 Physics Accepted
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).