Popular Science Introduction to Medium Circulation Topological Structure. The overall appearance of this topological structure is close to a standard sphere, uniformly wrapped by a homogeneous medium. It has a regular and rounded shape without any visible tensile deformation or angular deviation under conventional observation, which perfectly fits the macroscopic spherical symmetric appearance characteristics of microscopic elementary particles and stellar celestial bodies, and also complies with the physical observation conclusions of the electron electric dipole moment (EDM) experiment. At the internal core of the structure, two sets of closed elliptical circulation systems with different sizes and completely perpendicular orthogonality in spatial position are constructed. The two ellipses share the same centroid, without any deflection angle or trajectory intersection, and coexist stably in a three-dimensional nested form. Relying on the absolute orthogonal arrangement, the global conservation of angular momentum and mechanical balance of the whole structure are realized, eliminating the imbalance of intrinsic stress. Along the central axes of the major and minor axes of the ellipses, two mutually perpendicular through-type ultra-low density medium regions are naturally formed. These regions are not solid hollow holes, but exclusive channels formed by the medium fluid gathering to the outer side under the action of high-speed circulation centrifugal force, resulting in extremely sparse medium distribution at the axis center. This channel is not only the weakest point of structural mechanical strength, but also the core transmission path for two-way exchange of zero-point energy, angular momentum and energy, just like the "energy breathing hole" of particles and celestial bodies, ensuring the long-term stable operation of the structure. In conventional energy environments, the internal elliptical circulation structure is completely shielded by the outer medium. Only under ultra-high-energy impact disturbance, the axial low-density regions will take the lead in morphological breakthrough, and the internal ellipsoid intrinsic structure can be revealed.
Chengbin Song (Fri,) studied this question.