On a dynamic ontic wave model of quantum collapse and measurement

This work introduces a novel model of quantum entities as physical, spatially extended wavefields, forming the basis for a realist framework for quantum measurement and collapse. Unlike interpretations that postulate hidden variables, observer-induced effects, ad hoc stochastic elements, or multiverse branching, this model derives the Born rule as a consequence of local physical interactions - involving kinetic energy transfer at or above a threshold - acting on an extended wavefield. Central to the model is a reinterpretation of the Heisenberg uncertainty principle - not as a statistical or epistemic limitation, but as a dynamical relation between kinetic energy transfer and wavefield contraction. This framework yields testable predictions about how weak, intermediate, and strong quantum interactions modulate spatial localization - predictions consistent with existing experimental findings. The upshot is a unified, falsifiable alternative to prevailing interpretations, and a foundation for a broader research program in wavefield interaction mechanics.