11. Thoughts on the 3D Spatial Arrangement Matrix of Microscopic Particles
11.1 Spatial Arrangement Matrix Representation of Electrons: To ensure the observed spherical symmetry of the electron’s electric field, its structure must comprise at least four or more SEQ in a 3D (possibly multi-layered) configuration. Additionally, the electron’s structural matrix may undergo rapid multi-axis rotation. Estimates based on electron mass suggest this matrix contains a large number of SEQ.
11.2 Representation of Electric Charge: Electric charge may correspond to the intrinsic multi-layered, multi-axis rotational dynamics of the structural matrix governing microscopic particles. All electric charged microscopic particles are embedded with analogous substructures.
11.3 Fractional Charges of Quarks: Fractional charges cannot exist in isolation but depend on SU(3)-mediated collective effects of quark confinement. The underlying mechanism suggests that when gluons between quarks disintegrate, the quarks must either likewise disintegrate or undergo reintegration.
11.4 Annihilation and Decay of Microscopic Particles: The annihilation or decay of microscopic particles fundamentally arises from the disintegration or reintegration of their spatial structural arrangement matrices.
11.5 Scarcity of Positrons: The intrinsic spin of an electron is essentially the orbital rotation of SEQ in the electron’s structure around the electron's center. Positron scarcity emerges from their interaction with the fixed-chirality ground-state spin of SEQ, inducing instability of their structural matrices, a mechanism that simultaneously explains parity violation.
