The electron forms around the proton as discussed earlier in the thread (post #2). The surface of the proton serves as a boundary just inside the vacated space that originated as the EEPs in the proton became synchronized. The vacated space serves as the ultimate low energy density environment setting up an energy density differential. EEPs surrounding the vacated space immediately respond by filling the vacated zone as they attempt to equalize the energy density. The electron forms from this onslaught after the stable surface of the proton is established.

Filling the zone, i.e. equalizing this unique energy density differential is not just a casual shift of EEPs toward the surface of the proton. It is a rush that crams EEPs into the zone like the three stooges all trying to go through a doorway at the same time. This swarming quickly completes the construction of the proton. The swarming does not stop when the proton is complete; the electron forms next from this same process.

The electron underneath the “weight” of the continuing swarm of EEPs reaches capacity and sloughs excess EEPs in the form of a photon like a little bullet forced out of the cloud at the speed of light.

The energy of the photon is derived from the energy differential between the vacated zone surrounding the proton, the high energy density of the swarming EEPs, and the variable energy density capacity of the electron (different n states for comparison with mainstream). In other words the energy density differential in the zone is so great that the variable capacity of the electron is reached, extending the election volume beyond the stability of the initial rest state, and the electron emits the photon, stabilizing the electron at rest in the zone and under control of the proton in a one-to-one EEP relationship between the surface of the proton and the electron cloud.

The sloughing of the photon collapses the electron which again creates an energy density differential that is again filled by swarming EEPs continuing the photon sloughing process to maintain the rest status of the newly formed electron.

The hydrogen atom now exits and hydrogen atoms make up all of the matter and mass in the entire universe at this early stage of matter formation.

The number of EEPs in the electron is determined by the number that can come in contact with that surface at any instant. There is a one to one relationship between the number of EEPs on the surface of the proton and the number of EEPs that make up the electron cloud at rest. The proton is quite dense relative to the unsynchronized EEPs rushing its surface. The electron is much less dense because it is a chaotic cloud of swarming EEPs instead of a stable and orderly configuration of EEPs like the proton. The difference in energy density between the proton and the electron should make for the huge size differential of the electron relative to the proton.

The electron is a quantity of EEPs in the zone but the individual EEPs are always changing position as they approach the surface and are denied entrance only to be replaced by another of the swarming EEPs. The turnover of the EEPs that form the electron is continuous. The electron changes its EEP content all of the time and the number of EEPs that make up the electron is a variable. The low end is fixed at the number of EEPs on the surface of the proton, and the high end is determined by the level of excitement associated with the electron as it goes through the process of gathering EEPs over and above the fixed low end EEP capacity of the electron and before it emits a photon (and as it absorbs photons emitted by other H atoms).

The relationship between the mass of the electron at rest and the mass of the proton, both consisting entirely of EEPs, a relationship used by the mainstream, is accepted by the ISU for purposes establishing the size of the average EEP diameter in the proton. I am using a 1:1,836 relationship between the mass of the electron and the mass of the proton for the calculations. This is the second relationship that I mention that now allows me to make the first estimate of the energy and size of the EEP.

In my next content post I will quantify the concept of an “average EEP diameter” and will post my first estimate of the energy value of an EEP, along with simple formulas used in the calculations.