This document presents the fifth iteration of the Temporal Measure Framework (TMF). Physical time is modelled as a measure with locally variable density f(t), reformulated progressively through fiber bundle geometry, stochastic field theory, and — in this version — topological manifold structure. The foundational postulates P1–P5 establish time as a structured measure governing radioactive decay anomalies, grounded in quantum vacuum physics. Seven new postulates P6–P11 and P10a extend the framework: time is a topological surface along which objects traverse geodesics (P6); existence requires energetic sustenance defining the arrow of time (P7); motion detection requires temporal structure, resolving Zeno’s paradoxes at the ontological level (P8); the topological surface can locally fracture due to external factors (P9); observable time is a topological cross-section of an n-dimensional temporal manifold Lⁿ (P10); existence is the realization of a physical object within that cross-section (P10a); fracturing is predictable when compression exceeds a critical threshold (P11). Eight independently reported decay-rate anomalies (p = 0.0011) support the empirical prediction. A geometric discriminant distinguishing the vacuum hypothesis from the solar neutrino hypothesis is proposed.
Leonas Povilaitis (Wed,) studied this question.