| 8.5 |
A greater explanation of strong chemical fusion
|
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Under weak nuclear fusion, we
saw that Proton core structures are strongly attracted to forming relationships
under certain temperatures. This gave rise to the Hydro-Helio Atomics Matrix.
We also saw that in the process, ergon particles are attracted to forming inner
orbits around strong Proton cores, explaining why most heavier (larger)
elements in the Hydro-Helio Matrix are more magnetic and electrically
conductive. |
| |
We know that structures such
as Carbon, Oxygen and Hydrogen then form more complex structures (molecules).
We shall now explain how and why these structures do this. |
| 8.5.1
|
The latent potential for
electrons to orbit |
| |
As we explained, elements
over a certain size and configuration have Positrons and other sub atomic
particles located in orbit paths, within the overall structure. Because they
are where they are, these sub atomic particles effectively double and in some
cases triple the strength of their "perceived" personalities.
|
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According to the rules of Orbit (Chapter
6), these inner electrons/positrons are strong enough to attract "same family"
electrons to orbit (under the right conditions). At the back of Chapter 7, we
showed the latent potential for electron orbit and magnetons for each and every
element of the Hydro-Helio Atomic Matrix. |
| |
Importantly, we were able to show that
electron orbit of atomic structures is not without reason and that if no family
members are present in a structure, then electrons will not orbit. We also
noted that this has never been fully comprehended in contemporary scientific
models such as the idea of Ions and Valency.
|
| 8.5.2 |
Unfulfilled latent potential and fulfilled
latent potential
|
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From the Hydro-Helio Atomic Matrix we are able
to see that certain elements have a strong latent potential to attract
electrons, such as Carbon.
|
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When the latent potential is unfulfilled,
we can define that an atom as being in an Ionic state ( i.e. it has less
electrons orbiting than its potential permits). All elements are Ionic above a
certain temperature that does not allow stable electron orbits. |
| 8.5.3 |
Important fact about hydrogen |
| |
It is both an important and as yet
undiscovered fact about hydrogen, in that Hydrogen formed from Proton cores
have no natural attraction to electrons! In fact hydrogen made from Protons is
the only elements in the Universe that are purely and naturally neutral to
electrons. |
| |
This is because Hydrogen with a Proton at
its core have no structures within it that are of the same family group of
electrons/magnetons/positrons to attract the energis particles to orbit. |
| |
In contrast, Hydrogen with a Protoactive
core, is very attractive to electrons as the Protoactive is by definition the
largest family member of the electron/magneton/positron family. It also happens
to be radioactive ( i.e. will break apart under certain conditions). |
| |
Radioactive Hydrogen is more abundant than
neutral Hydrogen. However Radioactive Hydrogen principally bonds under weak
nuclear fusion to form many of the heavier elements of the Hydro-Helio Atomic
Matrix. This leaves the humbler neutral Hydrogen in apparent greater numbers. |
| |
As Hydrogen exchange is the foundation of
weak chemical fusion, the difference between radioactive Hydrogen and
electrically Neutral hydrogen is of critical importance. Understanding the
difference, allows a massively simplified understanding of the world of
molecules and chemical reactions, with significantly improved accuracy. |
| 8.5.4 |
Not forgetting the strength and rules of
Proton cores
|
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Under weak nuclear fusion, cores of
different strengths form the elements we have discussed. Importantly, we see
the rules of Orbit applying to core structures of the same family. In other
words, only cores of the same family type combine. |
| |
While we have now identified that most
atomic structures have latent potential to attract electrons to orbit, we must
not forget that it is principally atomic structures that determine what atomic
structures can and will form relationships with other structures. |
| 8.5.5 |
Definition of strong chemical fusion |
| |
We are now ready to define strong chemical
fusion. |
| |
Strong chemical fusion is when atoms form
3-dimensional structures with other atoms of the same nuclei family via the
co-dependence of hydrogen, hydroactive and ergon exchange.
|
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Determining the shapes of molecules |
| |
Contrary to everything you may have learned until now, with the knowledge of a few key rules all the possible molecular
shapes in the Universe may be determined, including: |
| |
| Their 3 dimensional shape; o The temperature at which they bond; |
| How they behave; o Other molecules that are related; o Bonding
strength; |
| Energis particle behaviour as a molecule. |
|
| |
All this information may be determined
without having to see a molecule, or even study a molecule in a laboratory. In
other words, we can make entire sense of the world of molecules, through
understanding the Hydro-Helio Atomics Matrix as well as the rules of strong
chemical fusion bonding. |
| 8.5.6 |
A major challenge to our contemporary
understanding
|
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What we are discussing is natural
personality groups justifying the reason certain elements bond with one another
way before we even consider how many outer and inner Hydrogen/hydroactives in
their structure and how many ergons (not simply electrons) these elements have
in their shells. |
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How is this possible? For what we have
just discussed is completely contrary to everything ever written about
molecular chemistry and biological sciences. |
| |
Let us re-cap part of the atomic structure
table we discussed in chapter 7: |
| |
| |
Element |
P |
ID |
Core |
Mid |
Outer |
CP |
MP |
OP |
CM |
MM |
OM |
M |
 |
Hydrogen |
1 |
H |
|
|
|
1 |
|
|
1 |
|
|
1 |
 |
Helium |
2 |
He |
|
|
|
2 |
|
|
4 |
|
|
4 |
 |
Lithium |
3 |
Li |
|
 |
|
2 |
1 |
|
4 |
3 |
|
7 |
 |
Beryllium |
4 |
Be |
|
|
|
3 |
1 |
|
6 |
3 |
|
9 |
 |
Boron |
5 |
B |
|
|
|
4 |
1 |
|
8 |
3 |
|
11 |
 |
Carbon |
6 |
C |
|
 |
|
4 |
2 |
|
8 |
4 |
|
12 |
 |
Nitrogen |
7 |
N |
|
|
|
6 |
1 |
|
12 |
2 |
|
14 |
 |
Oxygen |
8 |
O |
|
|
|
6 |
2 |
|
12 |
4 |
|
16 |
 |
Fluorine |
9 |
F |
|
|
|
8 |
1 |
|
16 |
3 |
|
19 |
 |
Neon |
10 |
Ne |
|
 |
|
6 |
4 |
|
12 |
8 |
|
20 |
|
|
| |
Looking at the beauty and the simplicity
of design of mother nature UCA, we can now consider the personality of two
vitally important elements for life: |
| |
Oxygen is super attractive to Hydrogen,
because Oxygen has four Hydrogen in stable attractive orbits. Because of its
core structure, the two outer Hydrogen provide good bonding partners. Hydrogen
bonds either 2:1 or 2:2 (HO, or H2O)
|
| |
Carbon is super attractive to Hydrogen,
Oxygen and to a lesser extend Nitrogen. 8 times out of 10, Carbon will want to
form bonds with Hydrogen, because they're the simplest.
|
| |
And with this powerful knowledge we can go on and
describe with precision how and why these atomic structures will bond the way
they do under the right conditions. |
|
| 8.5.7 |
Electrons are but one the means by which atoms form
bonds, electrons are not the end in itself
|
|
| |
What we are able to therefore say is that electrons
are but one of the ergon particles that hold together relationships between
particles. That magnetrons, gravitons, electron neutrinos, also play and
important part to play in the relationships between atomic nuclei. |
|
| |
Electrons are merely the largest collection of ergon
particles. They are not the sole basis upon which molecules relate. Electrons
come and go, but we see atomic relationships having greater depth and
complexity than simply the number of electrons or electron exchange. |
|
| |
This is crucial in understanding the limited influence
that electrons ultimately play in the overall desires of atoms to make more
complex structures. Atomic structures will build their relationships regardless
of the minor variances in electron counts. |
|
| |
When we consider electrons in the future, we should
consider attaching the word tolerance- that all atomic structures have a
certain tolerance to an abundance or extreme shortage of electrons. (It is not
perfect 1 extra electron or minus 1 electron theory.) |
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