Matter-Super sub atomics-The Super-Sub atomic elements



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The Super-Sub atomic elements

In the super sub-atomic and sub-atomic particle world, literally hundreds of different shapes have been observed. For the moment, we are concerned with the shapes that form the basic building blocks for the atomic world, via protons, neutrons and electrons.

From the probabilities and the fortis at work in our field of 26 near neighbours, the three most common arrangements of UNITA will be:

(1) 1 creator orbiting 1 destructive attractor

(2) 2 creators and 1 equatorial destructive attractor

(3) 1 creator orbiting two destructive attractors

Further shapes are also created as nearby destructive attractors and creators mix:

3 creator core, 2 destructive attractor orbit

3 destructive attractor core, 2 creator orbit

And of course, there is the combination of these shapes. Once a shape is created via fusion at high temperatures, it will not change unless those temperatures are reached again.

While there are many, many shapes of sub-atomic particles possible, it is the limitation that once bonds are created, they are near impossible to uncreate without extremely high temperatures. Therefore the simplest, strongest and most stable bonds also happen to be the most common.

6.24.1

Making sense of these sub atomic particle groups

You may be surprised ( or not surprised) to find that the model of sub atomic particles described on the previous, fits with the standard model of the basic building blocks of matter.

The "standard model" is an attempt by science to categorize particles in such a way that one day there might be unified theory of the Universe.

In terms of categorization, the standard model in parts remains fairly messy as transient particles are listed alongside the basic building blocks of creation.

However, some definitions are clear enough for us to give due respect to sciences hard journey and assign the most commonly used names to the complex particles described above. In science, there are commonly understood to be four families of sub-atomic particles

Anti-Quarks (Repulsors)

Anti-Leptons (non equatorial negative destructive attractors)

Quarks (Creation family)

Leptons (Non-equatorial destructive attractor family)

Quarks (creators)

Science has identified essentially six types of Quarks, behaving in pairs

"Up" and "Down" Quarks that combine to create structures such as protons and neutrons. "Charm" and "Strange" Quarks that create more exotic particles- the sort produced by deep space quasars and high energy cosmic waves

"Bottom" and "Top" Quarks that occurred briefly at the creation of the Universe and only occur fleetingly under intense states of pressure.

Science has identified that in the construction of protons and neutrons, the following characteristics.

Protons Protons appear to be made up of 2 UP QUARKS and 1 DOWN QUARK.

Neutrons Neutrons appear to be made up of 2 DOWN QUARKS and 1 UP QUARK

Neutrinos (destructive attractors)

Neutrinos are essentially the destructive attractor family and the family of neutrinos.We know of three types of neutrinos so far:

Electron neutrinos (slight negative charge)

Muon neutrinos (no apparent spin, therefore charge)

Tau neutrinos (no apparent spin, therefore charge)

Electron neutrinos are the largest of the three types of neutrinos of the destructive attractor sub-atomic family.

Cosmics

Cosmics are heavy core super sub atomics with a neutrino pair in outer orbit. They are rare compared to the other types of super sub atomic matter. However, they are the most destructive particles in the universe for matter. They are the source of elementary radiation.

Neutrons Neutrons appear to be made up of 2 DOWN QUARKS and 1 UP QUARK

Magnetons (non equatorial destructive attractors)

Electron Neutrinos

Electron Neutrinos are special. They form, not only the largest grouping of sub-atomic particles in the Universe, but they also form as well, as opposed to the poor non-equatorial destructive attractors.

Neutrinos form part of the structure of not only electrons but positrons. For that reason, electron Neutrinos "behave" very similarly to electrons and positrons. If a scientist were to try and pick them apart, they could mistakenly describe them as the same force- e.g. electro-magnetism.

But the Neutrinos attracted to form, like Gravitons, do not perfectly match the behaviour of electrons. Neutrinos that are the miniature "magnets" we've been waiting to understand have different particle field behaviour in a lower electron environment. They have larger field arcs, that are weaker because of the less number of electrons. They can also be warped far easier when other objects are placed at different positions, than electrons.

Electron Neutrinos are therefore why we have magnetism. Electron Neutrinos are the magic "glue" particles that web themselves between and outside objects. Because they are particles and behave both in form and as a particle field, we call Electron Neutrinos a fortis particle field.

6.24.3

When are Quarks and Neutrinos formed?

Quarks and Neutrinos are formed in the days and years after the "Breath of Life", the incredible col winds of Unita passes through as the Universe on its outer edges continues to expand. They are not and cannot be formed by Stars, Black Holes or Supernova.

For the moment, it is important to consider the tremendous pressures and densities (therefore temperatures) required to create Quarks and Neutrinos. The great cosmic nebulae, burning as het as any supernova, a precursor to the formation of stars in nebulae clouds of hydrogen, dust and sub atomic particles.

We are talking about temperatures of billions of degrees Celsius, far too het for a Star, no matter how massive to create Quarks. In fact the temperatures required are so high that not even Black Holes can deconstruct the basic configuration of Quarks or Neutrinos (something we will explain further in Chapter 9 on Stars and Galaxies).

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