The quantum measurement problem, which concerns the transition from quantum superposition to definite classical outcomes, remains a central challenge in physics. This report looks at a body of work that potentially could provide a more unified and falsifiable phenomenology for the quantum to classical transition. Discussed therein, the geometric and entropic principles of the Finite Path Integrals on Stochastic Branched Structures (FPISBS), which provide a physical reason for why collapse occurs, together with the statistical dynamics of the Event Driven First Passage Model (EDFPM), which describes how and when it manifests, and the bridge that connects them. The core statistical functions of the EDFPM are shown to emerge from the foundational entropic principles of the FPISBS, suggesting a path toward a physical theory. The recent, first ever experimental measurement of Quantum First Passage Time Distributions (QFPTD) provides direct empirical validation for core phenomenons, marking an important step in the study of quantum foundations.