C-Fig. 2 (continued).

B.  A prototype structure of the COM electron.

1.  Electron is composed of a core of dense matter (focal body) around which a criton swirl is revolving. It is a macron of the type presented in Fig. 1.  The preferred model for the criton swirl is a flexible, dynamic, ring structure that possesses an internal stability based on the relative internal velose of its critons that in turn react with the electron’s core as a composite. The electrostatic (C-Fig. 3 and C-Fig. 7) and magnetic properties (C-Fig. 5 and C-Fig. 6) of the electron are mediated by criton swirls.  Each criton is a vehicle for the transport of velose and a locus for the primary effects of crifor.

2.  When isolated or free to move in a conductor and in accelerated translational motion, the criton swirl of the electron assumes a perpendicular orientation relative to direction of motion.  Thus the location and clockwise rotation of the swirl coincides with the observed magnetic field of C-Fig. 2 A-4.  See C-Fig. 5 and C-Fig. 6 for an explanation of how magnetic fields are generated by criton swirls.  The proposed electron spin of the contemporary electron (C-Fig. 2 A-3) creates a magnetic field parameter that does not exist associated with the COM electron.