Black Holes as Recursion Collapse Pressure Wells
Authors/Creators
Description
General relativity’s Schwarzschild and Kerr solutions provide the quantitative description of black hole geometry confirmed by LIGO gravitational wave detections and Event
Horizon Telescope imaging; this paper does not challenge those results within their
domain of validity. Instead, it develops the geometric substrate from which black hole
behaviour emerges in the Cohesion Unified Field Theory. Black holes arise from recursion collapse pressure wells — the deepest low-pressure zones in a pressurised universe.
Collapse occurs when torsion density exceeds the coherence limit of n = 6 closure,
triggering catastrophic slip and inward recursion. The event horizon corresponds to
a structural-time boundary where recursion propagation is maximally slowed but not
halted: because the recursion resistance has a positive lower bound R0 = f(Ps+1) > 0,
structural time approaches but does not reach zero, singularities are geometrically
excluded, and information is preserved through recursion continuity. Spin, jets, accretion, and Hawking-type radiation arise from torsion density dynamics and slip phase
behaviour. This is the first geometric, mechanical, and scale-consistent account of black
holes within the Cohesion UFT framework.
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Additional details
Additional titles
- Subtitle (English)
- A Mechanical Interpretation of Extreme Low-Pressure Zones in the Cohesion Unified Field Theory
References
- Gilbert, D.A., Cohesion: A Unified Field Theory of Matter and Motion, v3, Independent Researcher (2026).
- Gilbert, D.A., The Pressurized Universe: Axioms, Consequences, and the Geometric Impossibility of Vacuum, Independent Researcher (2026).
- Gilbert, D.A., Scaling General Relativity: Why Einstein's Symmetry Layer Cannot Be Universal, Independent Researcher (2026).
- Gilbert, D.A., Calibrating R(Dst): The Density-Dependent Propagation Function in the Cohesion UFT, Independent Researcher (2026).
- Gilbert, D.A., Matter Formation as Trapped Recursion, Independent Researcher (2026).
- Gilbert, D.A., Electroweak Symmetry as Recursive Phase Alignment, Independent Researcher (2026).
- Gilbert, D.A., Dark Energy as Residual Pressure Gradient Drift, Independent Researcher (2026).
- Gilbert, D.A., The Binary Recursion Toggle: Hexpolar and Bipolar States, Independent Researcher (2026).