This article converts the particle and nuclear framework of DKMM into a set of concrete testable predictions. It proceeds from the assumption that the proton is the primary open vortex node of the Dynamic Cosmic Medium, the electron is a compensating node, and the neutron is a secondary compensated state of the proton regime. From these assumptions, the article derives predictions for the minimum neutron compensation of light nuclei, the limited capacity of the first layer, closure values of layered stabilization, the problem of the fourth layer beyond lead, low-energy retuning of nuclear nodes, differences between head-on and shear-like collisions, and possible state after-effects following high-energy events. The article does not address the astronomical or cosmological consequences of DKMM; those are reserved for a separate following article. The purpose of this work is not to present a closed numerical theory, but to create a predictive framework that can be compared with existing and future experimental data.
Aleš Hrůza (Mon,) studied this question.