Chapter 2

Many Mini-Universes

The forgoing is taking place at the same instant duplicate processes are underway. Super energy is turning into matter throughout the volume of this composite energy, and the universe is already billions of light years across before the startup processes are done. Finally, there is little Composite Energy remaining in this part of the universe after all cells have come together. The lingering globs of super energy maintain their characteristics. They still repel matter when it comes near. Such globs may become mysterious to scientists billions of years from now as dark energy.

Building the atom comes about as each cell merges with its neighbor and finds its new friend beneficial. When it does, it presents an opportunity to begin a foundation of something greater than the two separately. Then as that combination grows, and more filaments create other products with each new merge, they become more useful. When it finds its new friend detrimental, that opportunity never occurs, and failed subparticles are born.

Soon we have a complete object, maybe two, which join up. Perhaps a full-fledged quark meets another, and then they meet another with the right qualifications to suggest a special behavior. A proton is born. Later an electron’s universe expands into the proton area, and more magic comes about—an atom, and the beginning of something very special.

The image below is a representation of the universe at only a few seconds old.

At 300,000 years old, things begin to settle down. While really unknown, the universe could be as large as 150 billion light years across at only a few years old. The image below represents a small section of the universe at that young age. Each mini-universe has chowed down on its neighbors to reach the size. And each one continues scarfing.

In spite of space growing at 5 ¼ times the rate it should be, clumps of matter still cling to each other forming clusters. Soon they integrate into even larger groups which quickly become the whole.

Understanding how each universe gobbles up its neighbor is essential to grasping how the center of our Universe is located every place inside. For example, 13.9 billion years in the future every place on Earth will be at our Universe’s center. However, every place on Mars will also be at its center. One reason the reference is to “our Universe,” is that every person on Earth is at his or her universe’s center. That is, the universe begins everyplace at the same time resulting in an unimaginable number of sources. Unfortunately, there are as many universes as there are points, and each one can only reveal itself at the speed of light.

A mental conflict between physical distance and time distance arose when presenting the physical size of the universe and the size of the mini-universes or orbs. All of the newborns are 300,000 years old, so they are aging in parallel. Regardless of how many exist, they are still the same age, so the distance across all of the universes during that period should not be measured by time. Instead, a physical size should be calculated. It turns out to be over 35.27 quintillion statute miles across for these ten babies. One could probably push it and convert that distance to light years, but then that size could be misunderstood to be x years old. See what we mean about conflict?

Dark Matter

Not all filaments combine into elementary particles. They do not fit together properly to make up anything worthy of working with others. They are failed fundamental particles that form up in large groups, lumps of filaments if you will, that lie around and do nothing. Yet they will influence our Universe. These failed bits of subparticles will be known as dark matter in the far future.

In 84% of its attempts, our young Universe fails in manufacturing viable products. That number includes matter-antimatter collisions which act as if that matter just up and disappears. Imagine this. Only 16% of composite energy makes its way to becoming worthwhile particles. That means a lot of extra space, brought on by failed filums at making something useful, can be used to separate meaningful matter products. The separation exceeds the remaining super force’s ability to gather all matter together at the universe’s center point. Such an enormous distance between large groups of particles reduces the force of flux, so it has no power over the whole. Its power influences local groups only. That extra space also allows inference of an expanding universe. The positive side is that a lot of energy reservoirs are hanging around as dark matter assisting in the makeup and control of yet-to-be colossal galaxies.

This is another imagination exercise. Suppose that all attempts of changing composite energy to meaningful matter were successful. That means that large voids would never exist. That means that giant galaxies and other stuff would fill these holes. That means that future intelligent beings would never be able to see through these bright balls of matter to discover such a large universe. It would be interpreted as being only a few million light years in depth, and along with local stars and galaxies, the night sky would be glowing with unseen objects—just unresolved light beams scurrying across the sky.

And, it means that the remaining super force could gather all matter together and crush it into one super-duper black hole. Perhaps to be recycled someday, but matter would still be gone resulting in a failed universe. It may have happened before.