Dynamic Cosmic Medium Model as a Unified Framework for Cosmology, Matter, and Physical Processes

This article presents the Dynamic Cosmic Medium Model (DKMM) as a unifyingconceptual framework for interpreting selected problems in cosmology, gravity,matter, and fundamental physical processes. The aim of the text is not to claim thatDKMM is already a fully mathematically completed or experimentally confirmedtheory. The aim is to show that various open questions in modern physics can beunderstood within a single common picture as manifestations of the state anddynamics of a real medium that fills space.In DKMM, space is not identical with the medium. Space is the framework ofpositions, distances, and arrangement, while the dynamic cosmic medium (DKM) isthe real physical environment that fills this space. Vacuum, in this view, is notemptiness or a zero state, but the equilibrium state of DKM with a positive baselevel. There is no negative medium; negative values may only be deviations fromthe equilibrium state of the same positive medium.The basic concepts of DKMM are the state of the medium, state gradient,circulation, excitation, stable node, retuning, and slowing of processes. Matter isunderstood as a stably organized state of the medium. Particles are notindependent objects inserted into emptiness, but stable nodes or circulatoryconfigurations of DKM. Gravity is interpreted as a consequence of state gradientsof the medium, not as a property of empty space. Redshift, dark energy, and theexpansion of the universe may be read within this framework as consequences ofwave propagation and source evolution in a variable medium. Dark matter may beat least partly a consequence of a missing model of the medium, its state gradients,galactic circulations, or relic compact structures.The article summarizes the main directions of previous DKMM works: absolutetime and medium, the filtering role of the medium in lunar micrometeorites, openparadoxes of cosmology, the cyclic universe and the Big Bounce, the stability ofmatter, two types of antimatter, and the principle of circulation. Finally, the1limitations of the model and possible future research directions are formulated,especially the mathematization of basic relations, simulations of state gradients,immediate experimental priorities, and the search for testable differences betweenDKMM and the standard interpretation of physical observations.