Evolution of the Wave-based Universe (Part 3)

In the last post, I described the sequence of events centering around the very first time in the new Universe that a small number of essential elements had essence cascade into the S₁ state. We ended up with a collection of elements with distribution classes of:

• [.16807,?,?,?,?,?,.000729]
• [.117649,?,?,?,?,?,.000729]

After cohesion collected like distributions into densities, the Universe looked something like this:

The Space-based expression of the Universe sometime after after the second cascade event introducing essence into S1 and S2 (but before the third such event). Most elements remain of the same size/density, but some start to get smaller and collect together.

The elements in the [.117649,?,?,?,?,?,.000729] class would be the next to experience a cascade event. Again, whether or not one of these elements actually cascades into S₂ or S₁, no new elements expressed in Space – only some would get smaller in size. In fact, given that cascade events happen more frequently when an element has less essence in S₇, there would be many (somewhere between 10 and 1000?) more cascade events that don’t result in any new elements expressed in Space before the next one that does affect elements of the distribution class [?,?,?,?,?,0,0] – and thereby expresses new Space.

So, until this point of new expression in Space is reached, smaller and smaller numbers of existing elements in Space will get more essence in S₁, making them denser and denser. As well, the variety of distribution of elements expressed in Space will increase dramatically, making the process of cohesion more and more complex. Because of this, cohesion will likely become less able to collect exact duplicate essential elements directly together, instead building densities of different, but similar densities. These densities will be centered on the previous simpler homogeneous densities seen in the last post. These centers will continue to trend towards being the densest parts of their respective larger collections, as their elements will also cascade (and faster than anywhere else).

These larger densities are the start of eventual Wave 1 galaxies!

Because no new elements have been expressed in Space, the overall size of the Universe will continue to contract. At the point just before the next elements are expressed in Space, the Universe would look something like the following.

The Space-based expression of the Universe immediately before the second introduction of new elements into the Space super-state. Elements start to have many different distributions with small/dense elements collecting together around denser cores.

At this point in the evolution of the Universe, there are some elements of the distribution class [?,?,?,?,?,0,0] ready to undergo the next cascade event. Some of them will cascade essence from S₃ to S₂, and some will not (as always). Those that do include a cascade to S₂ will now be expressed in Space in a handful of different distributions with S₁=0 – meaning that they will all be relatively large in size. So, the question is where will these new elements be expressed in Space – where will they start their journeys?

I believe that essential elements being newly expressed in Space follow the dictates of cohesion in that they are introduced in existing areas of space most resembling (on average) their own densities. So, an element of the distribution [d7,d6,d5,d4,d3,d2,0] would “pop” into Space at a place where that was the general distribution already. Following from that, since the least dense average distributions of elements already in space happen furthest from the evolving “galaxies”, the newly expressing elements would be introduced in what might be termed the “depths of intergalactic space”.

The following map marks these least-dense locations with red dots (not meant to mark actual collections of elements, but just potential “entry points” for new expressions in Space).

The red dots show where essential elements newly expressed in Space would be added to the growing Universe. Each location would attract elements of equal (or very similar) distributions.

All newly expressed elements would be of very low density, so none would show up as blue in our map of the Universe. Also, a large number of elements (about 80% of the number of elements in the initial expression in Space) would be introduced at this point. Since these newly introduced elements are generally larger than those from the first introduction (which have since cascaded into smaller sizes on average), this event would approximately double the size of the Universe at that point. The effect would be to push the evolving galaxies further apart from each other, while mostly maintaining their overall distribution in the Universe. This might look like:

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.

I’ve left the (lightened) red dots in the map for reference.

In the next post, I’ll describe how even newer galaxies are created, how the points where newly expressed elements are introduced evolve over time, and how cascade events start happening on a more regular basis.