Evolution of the Wave-based Universe (Part 6)

In the last post, I leapt forward to how the Universe would look after 20 introductions of essential elements into Space. No new galaxies were being created, and the existing galaxy clusters were getting further apart from one another and denser within themselves. Because of a lessening of new elements being introduced within galaxy clusters, occasional galactic collisions and consolidations were occurring. The Universe at this point looked like the following:

Here’s what the Universe would look like after 20 introductions of essential elements into Space. Note that in some places (orange circles) galactic collisions have occurred.

The combination of the probabilistic nature of whether cascades occur during cascade events and the proliferation of new classes of essence distributions would cause the frequency of Wave 1 element introduction to increase over time and the relative size of these introductions to decrease over time. The remainder of the cascades of Wave 1 elements into Space (and into denser and denser forms once in Space) would continue for billions of years. The basic effect of those continued introductions and overall cascading would be the same, though – existing galaxies and galaxy clusters would get denser and denser and further apart from each other.

Let’s fast forward to approximately 13 billion years (Gyr) after the initial cascade that started the Universe. Wave 1 elements have been introduced into Space over a 10 Gyr period and have been evolving into denser forms (each at its own, independent rate and sequence) and collecting in larger densities. While most of the 3D area in Space is still taken up by ultra-low-density elements (what we perceive as empty space), many more total elements are represented in much denser forms, collected primarily within galaxies. Let’s say that approximately 90% of the 50% of overall elements that cascaded at that very first moment of time (i.e., the Wave 1 elements) have, by this time, cascaded into representations in Space, leaving 10% of 50% in the distribution class [?,?,?,?,?,0,0]. The large majority of these 5% of overall elements would still be of the distribution [.7,.3,.0,0,0,0,0].

Because the amounts included in each new introduction has, by this time, decreased to a relative trickle, most of the elements that we perceive as empty Space would have undergone some further cascades after their introductions into Space. This would leave relatively few areas in the Universe with ultra-low-dense distributions similar to those seen at the beginning of the Wave 1 introductions into Space. The Universe map might look something like the following at 13 Gyr.

Here’s how the Universe looks at ~13 Gyr, as Wave 2 is set to begin. The shades of blue represent levels of density and the white dots the areas of lowest density.

Let’s examine the new map.

1. Notice that the overall diameter of the Universe has increased to ~3U – meaning that the overall volume is about 27 times as much as at the first introduction into Space (about 10 Gyr earlier). While the total number of elements expressed in Space has increased many, many times more than this, the average increase in density of the individual elements has counter-balanced most of the overall expansion.
2. Notice that all the galaxies are now represented by black dots. This indicates that they have all evolved, over the last 9 – 10 Gyr, into similarly dense structures with similar black holes at their cores.
3. I have used varying shades of blue to indicate the different overall densities of intra-cluster and inter-cluster space. While it would all appear to us as “empty space”, the space within clusters and immediately around them would be denser than that further between clusters. While I’ve only used three shades of blue, there would, in reality, be many more density levels.
4. I have used pure white circles to represent the small areas in deepest inter-cluster space where the density is the lowest, where elements on average are similar in distribution to new elements that would be introduced into Space.

At this point, while the Universe represented in Space continues to evolve, the essential elements that did not undergo a cascade from S₇ to S₆ at the beginning of time (that is, the 50% of all elements still at [1,0,0,0,0,0,0] distribution) would experience their second cascade event. 50% of these 50% of elements (=25% overall) would now undergo a cascade into distribution [.7,.3,0,0,0,0,0], starting a second wave (Wave 2) of essential elements heading down the inescapable path towards expression in Space.

[Bear in mind that Wave 1 continues to happen after Wave 2 begins – there are still 10% of the Wave 1 elements that are not expressed in Space, and all Wave 1 elements continue to follow their own individual cascade paths while Wave 2 cascades occur around them, temporally.]

What then is the relative “size” of Wave 2? Wave 1 comprised 50% of all available elements with 45% (50%*.9) expressed in Space at this moment in time (13 Gyr). Wave 2 contains 25% (50% of 50%) of all available elements, so we can expect that it will result in a further 22.5% of all possible elements being added to Space over the next ~13 Gyr. So, at the beginning of Wave 3 (at ~26 Gyr), there will be 67.5% of all possible elements introduced into Space by then.

In the next post, I’ll start showing how Wave 2 elements actually get introduced into Space and how that makes the evolving Universe more beautiful and complex.