C-Fig. 5. The Genesis of the Field about a Current Carrying Wire and the Formations of the Mutual and Tandem Swirls

A.  Field about a current-carrying wire.  When an electron is governed by a translational impetus, such as an EMF across a conductor, the potential to form the electrostatic bond between the positive and negative charges inside the conductor is reduced.  Because the direction of rotation of the criton swirl assumes a perpendicular orientation with a clockwise rotation relative to the direction of the electron’s approaching motion, a criton-swirl field surrounding the wire is produced.

1.  Representation of a criton-swirl field around a wire.

2.  Response of a magnet to the direction of motion of electrons.  When a compass manifests a specific orientation to a phenomenon without apparent physical contact, it is considered to possess a magnetic field and its direction can be assigned. Orientation of a magnet is mediated by criton swirls.  See C-Fig. 6.

3.  Conventional representation of a magnetic field about a current-carrying wire.

4.  Patterns produced by iron filings around a current carrying wire.  Iron particles become induced magnets.

B.  When two electrons are forced to travel parallel or tandem paths in the same direction, resultant swirl patterns form between the respective criton swirls.  

1.  The mutual swirl. The development of the mutual swirl between electrons in parallel wires creates an attractive force between the wires. 

2.  The tandem stack.  The movement and orientation of electrons along a conductor as indicated in C-Fig. 5 A-1 is facilitated by the formation of the tandem stack that helps mediate the EMF phenomenon.  The tandem stack allows a mutual attraction among electrons along the direction of translational motion.