Filamentation and Supercluster Formation in a Three-Phase Etheric Plasma develops a full physical explanation of the cosmic web, superclusters, clusters, filaments, and voids using the three-phase behavior of a frictionless etheric plasma displaced by quarkbases. The central idea is that the vacuum behaves as a continuous plasma whose effective dynamics change depending solely on the local displaced-volume fraction. At extremely low displaced volume, the ether behaves as a rigid medium, producing smooth and completely empty voids. As the displaced-volume fraction increases, the plasma enters a liquid-like regime that forms clusters, sheets, and large walls. Once the threshold for compressibility is crossed, the plasma becomes effectively gas-like and collapses into long, thin pressure channels: the cosmic filaments. Where several filaments intersect, the pressure reaches true minima, generating superclusters. The work shows that these three regimes—rigid, liquid-like, and gas-like—are not different substances, but different dynamic responses of the same frictionless plasma. The cosmic web, including its largest structures, emerges naturally from this phase behavior, without dark matter, without gravitational halos, and without metric expansion. The paper explains why superclusters cannot grow beyond roughly 200–300 Mpc, why voids remain perfectly smooth, why galaxy spins align along filaments, why spirals form only in filamentary regions, and why rotation curves flatten without invoking dark matter. The ether’s transition to a filamentary state is shown to be mathematically identical to the formation of smoke filaments, scaled up by dozens of orders of magnitude. This framework provides a single mechanism that explains all large-scale cosmic structure in a coherent, testable, and falsifiable way
Date: Nov 01, 2025
Author: Carlos Omeñaca Prado
ORCID: https://orcid.org/0009-0001-9750-5827
Resource type: Preprint
Publisher: Zenodo
License: CC BY-SA 4.0 International
Related links:
- https://zenodo.org/records/17716344
- https://archive.org/details/filamentation-and-supercluster-formation-in-a-three-phase-etheric-plasma
- https://www.academia.edu/145262454/Filamentation_and_Supercluster_Formation_in_a_Three_Phase_Etheric_Plasma