This work introduces the Flip Freeze mechanism, a local non‑unitary process in which a triadic network loses its ability to perform orientational reconstruction. We show that a black hole in TMD is not an object but a network state arising when the local orientational gradient exceeds a critical threshold and triads enter a frozen regime. The horizon emerges as a boundary of computational reachability, not as a geometric surface. The study provides a complete local mechanical description of collapse:– how Flip Freeze arises,– how the horizon forms,– why the process is non‑unitary,– how triadic radiation emerges at the boundary,– and how the energetic balance of the collapse is maintained without singularities or exotic physics. Triadic radiation is shown to be a purely local orientational process distinct from astrophysical gamma emission, which originates in active polar regions rather than at the horizon. The resulting framework offers a consistent, geometry‑free description of black hole formation within the triadic network. This paper is part of the TMD series and complements the foundational works on triadic dynamics, information conservation, and emergent Lorentz symmetry.
Aleš Kováč (Fri,) studied this question.
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