Version 1. 0. 2 Update: The Vortical Repulsion Refinement In this version, we have formally redefined the mechanical outward pressure within the black hole interior from "Centrifugal Force" to "Vortical Repulsion (Fᵥr) ". While "centrifugal force" provided a useful Newtonian analogy, it is often viewed as a pseudo-force in a continuous manifold. In the Vortical Gravity framework, the outward pressure is an emergent, real force caused by the 50/50 probability partitioning of the discrete lattice at the saturation limit (X to 1). Vortical Repulsion better describes the lattice's active resistance against gravitational collapse, establishing the Topological Equilibrium that maintains the Vortical Void (Hollow Core). This paper identifies the vacuum’s ``Discrete Temporal Symmetry Breaking'' (E t) as the fundamental engine of motion, redefining light as the saturation velocity of a discrete lattice within the irreducible temporal gap (dt). Moving beyond 2D holographic models, we propose that black holes are Volumetric Vortex Shells where information is maintained in a 3D probabilistic superposition. We derive a mechanical resolution to the singularity problem via the equilibrium of vortical repulsion and lattice stiffness saturation, resulting in a hollow-core vacuum topology. Furthermore, we demonstrate that relativistic time dilation is a direct consequence of motion probability (Pₘ) partitioning. At the event horizon, rotational demand saturates the lattice’s processing capacity, limiting temporal flux; this results in a quantized dilation limit at the vortical radius rᵥ, where the probability partition reaches its mechanical equilibrium.
Dong Hoon Oh (Tue,) studied this question.