Addendum I

All configurations of galaxies when first formed will depend on the distribution of the stars (produced in the Cataclysmic Collision).  This occurs as they are attracted to the central enermatia (also resulting from the same Cataclysmic Collision).   If the large majority of stars are in one particular location, then the form will be spiral.  When the stars are more or less equally distributed, then the form will be straight, with little or no curvature.

Regardless of the form the galaxy may have, as it ages the orbit of the stars will constantly change, and the distance from the central enermatia will gradually be reduced.  It is also possible that some stars orbiting in counter direction may collide as the galaxy contracts.  In this case they would join the central enermatia in less time than many of the other orbiting stars.  In any event, most of the stars will end up condensing into the central enermatia.

Addendum II

When a collision occurs, particle formation is one of the three things that happen immediately.  The particles resulting from the conversion of a large portion of the enermat  I call Omnitron 1.  From the conversion of much of the kinetic energy produced from the collision I call Omnitron 2.  Finally, the dispersions will go in two opposing (ever-widening) somewhat cylindrical paths.

The interaction among all of the omnitrons will result in splitting, and each omnitron will produce a large number of electrons, protons, neutrons and a variety of other sub-atomic particles.  As interaction continues among the new particles atoms of one element will be produced.  With the reduced amount of free energy available, and the increasing distances between particles, another element forms.  The process continues until much of the free energy has been used up, and the exo-enermat has ‘cooled’ appreciably.  The whole process of creating all of the elements, one at a time, probably takes less than a ten-billionth of a second.

In this process of producing matter the result is not a homogeneous ‘mix’, but rather concentrations of pockets of many individual compounds.  This manifests itself only in small bodies that are formed, but not in stars.

Addendum III

Nature’s way of conservation is to create a steady state.  This is made possible by a balance of creating matter (and in effect, ‘stored energy’) with the collisions of enermatias and the depleting of energy through continuous radiation from stars.

The cosmos is infinite, not a closed system and once energy is expended, it is gone.

I believe that the Law of Conservation of Energy and Matter is invalid.  Matter made up of ‘stored energy’ is constantly being created, and radiation from stars expends energy at a balancing rate.

Addendum IV

Referring to Table 1, the kinetic energy resulting from the collision of two enermatias can be equated to the energy lost through radiation from a multitude of stars.  Our sun emits 1.17 x 10⁴¹ ergs of energy per year.  If we were to take one trillion (1 x 10¹²) stars, each the magnitude of our sun, their total energy output would be 1.17 x 10⁵³ ergs per year.  By dividing this figure into the amount of energy at various velocities when two enermatias collide, we can obtain the number of years of radiation necessary to balance off the energy from a collision.  I have compiled Table 2 showing the amount of kinetic energy in ergs resulting from a collision of two enermatias, each the magnitude of our Milky Way, and traveling at six different velocities.  In the last column I show the number of years necessary for radiant energy to be dissipated from the trillion stars to equal the kinetic energy resulting from the initial collision.