Temporal Flow as the Origin of Quantum Delocalization: A Physical Consequence of Informational Saturation

The Stochastic Rupture (SR) framework postulates that wavefunction collapse is an informational phase transition triggered by the saturation of local holographic entropy bounds. A central corollary of this framework is the emergence of proper time as a function of local informational occupancy: dτ = dt, IPlanck χ, η, Acausal . (1)While previous analyses focused primarily on the collapse regime (χ → 1), this work explores the opposite limit (χ → 0), characteristic of microscopic quantum systems. We propose that the extreme temporal acceleration associated with low informational saturation provides a physical explanation for quantum delocalization. In this picture, the wavefunction describes a temporally generated ensemble of rapidly iterated configurations within a coarse external time slice. Apparent spatial superposition therefore emerges as a relativistic asynchrony between informational proper time and macroscopic coordinate time.