In the last post, I described the sequence of events centering around the second time in the new Universe that a small number of essential elements had essence cascade into the S1 state. Just after that introduction, we ended up with forming galaxies (from the first introduction of essence into Space) being moved much further apart by the newly introduced elements:
The Universe has just undergone its second introduction of essential elements into Space. The faded red dots represent where those “new” elements were introduced. Notice how the evolving galaxies are now further apart.
At this point in time, there would be millions of years before the third cascade into the Space super-state and the early-forming galaxies would be sufficiently far apart from each other that the majority of the newly introduced essential elements would be able to resist the cohesion forces from them and form new densities of their own as they further cascaded into S2 and S1. Some of the cascading elements would get drawn towards the early forming galaxies, however, making their densities larger and more varied.
Also, because of these newly-forming galaxies, the areas for where the next set of elements would get introduced would shift and likely multiply. The Universe, just before the third introduction might look like the following:
We now have two broad classes of galaxies forming, those from the first introduction and those from the more recent introduction. The red dots mark where elements from the third introduction will shortly be introduced.
Notice that the red dots, which mark where the next essential elements to be introduced into Space would appear, are of two different shades of red. This is to recognize the different distributions cascading into S2, each with their own quantities of essential elements. The darker red dots represent those places (let’s call them “points of introduction”) where greater quantities of elements would be introduced and the lighter red dots are for where lesser quantities would be introduced. (In reality, there would be many more distinct levels but, for simplicity’s sake, let’s work with two levels for now.)
So, as the third set of essential elements cascades into expression in Space, the individual galaxies (from the two separate categories) would be “pushed” further and further apart. However, since some points of introduction have a greater quantity of new, large-sized elements and some have a lesser flow, the overall effect would be that galaxies groups/clusters would start to be formed.
We should also consider at this point, how these evolving galaxies themselves would start to move closer together through cohesion. As they become more and more dense, galaxies would exert stronger and stronger attractions for each other and would start to move together. What keeps them from colliding and merging with one another? Two things, primarily: first, the distances between galaxies is great – many millions of light years separate them on average; second, points of introduction that lie somewhere between them continue to add relatively fewer low-density elements that push them further apart – not stopping their inevitable attraction through cohesion, but putting more distance between them, which also lessens the cohesive force.
If we take all of this into consideration, the map of the Universe might look something like the following immediately after the third introduction.
Here’s the Universe immediately after the third introduction of essential elements into Space. Galaxies are starting to cluster together. The dark red dots are left in for reference.
Again, we’ll assume that due to the timed nature of cascades, the next cascade won’t happen for millions of years. This gives the existing galaxies time to individually become more dense and to move closer together (through cohesion), and for some of the elements introduced at the dark red points of introduction to form a third class of galaxies.
At this point, we’ll just represent individual galaxies as equally sized solid-blue dots – the darker the shade of blue, the older (and denser) the galaxy.
Before the fourth introduction of elements into Space, the Universe would look like this:
Here’s what the Universe would look like before the fourth introduction of essential elements into Space. The clustering of galaxies continues, with new “third-class” galaxies forming and moving into nearby clusters.
In the next post, I’ll describe how this process of introduction-of-elements-and-new-galaxy-formation changes into more of an introduction-of-elements-and-galactic-consolidation phase.
Filed under: Predictions and Tests, The Model
