Matter Stability in the Dynamic Cosmic Medium Model (DCMM): From Quantum Solitons to Technological Horizons and a Call for Institutional Validation

This article completes the formulation of the Dynamic Cosmic Medium Model (DCMM) by extending its principles to the microscopic scale. While previous parts of this series demonstrated the model’s ability to resolve cosmological paradoxes (dark matter, dark energy, the Big Bang singularity) without invoking exotic entities, we show here that the same fundamental mechanism the interaction of matter with a physical medium of variable density (ρ), pressure (P), and drag (F∝v2) ensures the stability of atomic structures and nuclear forces. We demonstrate that electrons function as stable solitons (vortices) in resonance with the medium, thereby eliminating the problem of radiative collapse. Protons and neutrons are identified as ultra-dense, topologically locked knots of the medium, where the "strong interaction" corresponds to extreme local pressure gradients. We show that the apparent contradiction between cosmic drag and the stability of planetary orbits or atoms is resolved by the mechanism of local corotation and phase transitions of the medium near massive bodies. Thus, the DCMM offers a unified physical framework that consistently describes phenomena from subatomic particles to the evolution of the entire universe using a single substance. This work explicitly identifies areas (precise determination of coefficients k and γ, reproduction of the CMB spectrum, N-body simulations) that require the computational capabilities of specialized institutions, and formulates an open call for the global scientific community to apply the equations of the DCMM to observational data. As an illustration of the model's practical potential, we discuss the concept of advanced propulsion based on manipulating the properties of the medium ("Needle Warp").