Introduction
In this
chapter we will discuss the ways in which Electromagnetic Energy travels
through liquids.
As we discuss
the traveling of the photon system through a liquid, you will begin to see some
important concepts more clearly. The first of these is the difference between
internal speed of the photon versus rate of the photon to travel through the
liquid. The distinction is important.
In brief: the
photon itself never slows down. The photon always travels at the same speed.
However, due to the obstacles (the molecules of the liquid) the photon system
takes longer to travel through the substance than in empty space.
You will also
begin to understand the ways in which the photons can interact with the
molecules of the liquid, and be altered by this interaction. This can lead to
variations such as: full absorption; partial absorption; deflection at various
angles; and passing through unchanged.
Review
of the Photon System
Before we
begin, let us briefly review the physical structure of the Photon System. We
begin with the Photon Core. This core is a solid sphere, which contains an
enormous amount of energy. Attached to this core are two sets of energy
strings: Electric and Magnetic.
The Photon
Core is like a high speed train; the Energy Strings are like the Passengers on
that train. Thus, the Photon Core travels at a very high speed, from one
location to another. The Energy Strings will come along for the ride - until
circumstances encourage the strings (some or all) to get off the core.
This is the
Photon System.
Liquid
Behavior: Analogy of Christmas Shoppers
To understand
the way the photon system travels through the liquid, we can use the analogy of
Christmas Shoppers.
At a typical
shopping mall during the Christmas season, there are numerous people. It is
crowded. Each person is going his own way. Sometimes with the others, sometimes
crossing to get somewhere else. Yet but because there are so many people, the
individuals move very closely together. Indeed, the shoppers bump into each
other, as they try to cross paths.
This is
exactly how water behaves. Water molecules are individual entities, going their
own ways. However, they are close enough together to be generally packed.
Therefore, just like our Christmas shoppers, the water molecules have
individual movement, yet are close together. This means that water molecules
generally flow together, in group movements, as well as bumping into each other
as different molecules attempt to go in different directions.
All of this
bustling, tumbling, bumping into each other is what liquid molecules do. You
know from experience that it takes a long time to travel through a crowded
mall. The same can be true of any object - including a photon system - to
travel through a liquid.
Photons
Through Liquid:
Analogy
of Child Among Christmas Shoppers
Now that we
understand the behavior of the liquid, let us look at the photon as it travels
through the liquid. Again we will return to the analogy of the Christmas
Shoppers, with a small child to represent our photon.
A small child
can run very, very fast. You know this. Allow a child to roam in an empty
meadow, and she will run very fast from one end to the other.
However, place
that same child in the crowded mall at Christmas time, and even she will have a
difficult time getting through. She will push ahead, but often be blocked.
On the other
hand, she has an advantage. Being small, she can find the holes between the
adults. Slimmer and shorter spaces that most people can’t squeeze through…she
can easily slip into and race ahead. (Until, of course, she runs into another
wall of adults).
Therefore,
while she is usually fast, and is small enough to move through the smaller
areas between people…she is hindered in her traveling. It therefore takes her
longer to get where she is going, than on that empty meadow.
The same is
true for our photon in the liquid. The photon is normally very fast, but here
the photon is hindered by all the molecules in the way. The photon however is
very small, and like our child, can find the empty spaces to wander through.
Therefore, the
photon system has a desire to move forward, and seeks the spaces where this is
possible. Yet the photon system is hindered by all the molecules moving and
tumbling in the way. This means it takes a longer time for the photon to travel
through the liquid, then it does in free space.
Has the speed
of the photon changed? No. However the rate for the photon to travel is much
slower…simply due to all the obstacles in the way.
Speeding
Up Again When Leaving
The photon
speeds up again when it leaves the liquid. More accurately, the photon never
changed it speed. Rather, the photon is allowed to travel freely,
unhindered…which is faster than it was when in the liquid.
Again we
return to the analogy of the child in the crowded mall. When she is free to
roam in the meadow, she can run very fast. Yet here among the crowds of people,
she is blocked, and must meander her way through the spaces. The progress is
slow.
Yet, she
eventually passes all the other adults. Through her squirming and sliding into
the small spaces between the adults, the child eventually makes her way through
all of them…and emerges in the very front.
Whew!! It took
a lot of work, but she is now ahead of them all. At last there is nobody in
front of her. Now she can run again…at her usual fast speed.
The same
situation occurs with our photon system in the liquid. In space, the photon
travels extremely fast. In air, our photon also travels fast…though sometimes
hitting a few air molecules now and then. As the photon hits the liquid - such
as a glass of water - the photon seems to slow down dramatically. This is
because the photon is hindered by all the liquid molecules.
However, the
photon is very small, and can find spaces to get through. Eventually the photon
passes among the many molecules in the way, reaching the other side. Finally,
when the photon leaves the liquid, and back into the air, the photon is no
longer hindered. The photon travels its normal fast speed. (Though with a few
bumps in the air molecules along the way).
Analogy
of Han Solo and the Asteroids
There is a
second analogy we can use to understand photons as they travel through liquids.
This is Han Solo traveling through the asteroids.
In the second
Star Wars movie, “Empire Strikes Back”, there is a scene where Han Solo pilots
his Millennium Falcon through the Asteroid field. This scene is almost exactly
how a photon moves through a liquid.
Using this
analogy we not only visualize how photons travel through a liquid, but also see
what happens as photons are bumped off course, or absorbed completely.
A video clip
of Han Solo in the Asteroid Field can be found here: https://youtu.be/TKsVVmOGV9I
Watch the asteroids.
They are coming from all directions. They tumble and roll. This is exactly the
way liquid molecules behave.
Now look at
the space ships. They are much smaller, are trying to find their way. The ships
fly through the empty spaces…to the other side of the asteroid field. This is
exactly what photons do. When photons enter a liquid, such as water, the
photons want to keep flying along…through the empty spaces between the
molecules…and exit the liquid.
You will also
notice how difficult it is for a space ship to pass through the asteroids
without being hit by an asteroid. Indeed, you see the Millennium Falcon being
hit by asteroids a few times. You also see some of the Empire’s ships crashing
completely into other asteroids. It really is almost impossible for any space
ship to enter the asteroid field without being bumped, hit, or destroyed
completely.
The same is
true for a photon entering a liquid. Any photon which enters a liquid will be
hit by one or more molecules along the way. This leads to several options for
the photon, all of which are seen in the video analogy:
1. This could
just be a glancing blow, which will deflect the photon at an angled path. (In
the same way as the Millennium Falcon being shaken by glancing blows of
asteroids).
2. The photon
could lose a few energy strings, when hitting the molecule at just the right
angle - in the same way that a ship would lose a few parts after being hit.
3. Or, the
photon could be completely absorbed, after a direct hit. In this case, the
original photon would never reach the outside of the liquid. This would be
similar to the crash and total destruction of the ships into the asteroid.
Therefore we
can easily visualize photons being bumped and hit by liquid molecules, by
remembering the Han Solo in the asteroid field. In both cases, the goal is make
it through the tumbling objects safely. Yet in reality, the odds are very high
for being hit multiple times on route.
For the
photon, this can result in three main possibilities: 1) being deflected at an
angle, 2) partial removal of energy strings after being hit (this is also known
as “partial absorption”), or 3) complete absorption of the photon system.
Of course no
analogy is perfect, and in this case there is one difference: photons are not
piloted. The ships in the asteroid field have an advantage of being manually
steered through the spaces. The photon does not. Therefore the photon will be
hit many more times by molecules than any ship through an asteroid field.
However, the situations are very similar, and the visuals are almost identical.
Photons
Bumping into Molecules: Resulting Options
As stated
above, when a photon travels through liquid, the photon will likely bump into
many molecules along the way. The main options, as listed above, include: 1)
Deflection, 2) Loss of Energy (and likely deflection), 3) Complete Absorption. Here
we will describe the options in more detail.
Factors in
Options
The options
depend primarily on the electric and magnetic fields. Specifically: which
direction these fields are pointing, and how long they remain in that direction
(from the pulsation rate), when the photon system encounters the molecule.
In order for a
photon to be partially or totally absorbed, the energy fields must match the
energy fields of the object they encounter. That is, the fields must be
traveling the same direction, at the same time. When this occurs, the energy fields
of the EM Photon System will join with the fields of the other particle. This
is what leads to partial or total absorption.
In contrast,
when the fields are pointing in the opposite direction when they meet, then the
fields will repel each other. This will result in deflection of the photon,
without any loss of energy.
It also helps
if the energy fields are pointing in the same direction for a longer time. A
photon with lower energy, for example, will have a longer pulsation frequency.
This means that the energy fields will point in one direction for a longer
time, and more likely to be partially or totally absorbed.
Similarly, if
the liquid is colder, or denser, then the motion of the molecules themselves
are slower. Allowing greater time for energy strings to join from one particle
to another.
The Basic
Options
When a photon
hits a molecule, many things are possible. This depends on what exactly the
photon hits, and the position at which the hit occurs. However, we can make
some broad statements.
1. Total
Absorption: This occurs when the photon system enters into a particle. Each
particle of the atom (electron, proton, neutron) has surface holes. The photon
is much smaller than these surface holes, and can therefore enter into the
particle easily. This is total absorption.
**Notice how
we again see this in the Han Solo video…as they look for caverns to dive into.
The photon will enter protons and electrons in a very similar way**
2. Partial
Absorption and Energy Loss: This occurs when some of the energy strings of
the photon are removed, but not all. This usually occurs when a proton has
magnetic or electric energy strings flowing in the same direction as those of
the photon. Some of the energy strings of the photon will then join their kind
(magnetic or electric) of the proton.
Thus, some of
the energy strings physically connect to the energy strings of the photon…like
Legos…and pull away from the photon system. The photon system goes on its way,
though with less EM energy (and a shift to lower frequency) than before.
Note that the amount of energy transfer will depend on the strength of the new energy string that is created. Using the Lego analogy again, if we stack 50 Lego’s together, then it is possible to break the stack almost anywhere. Where will it break? Which end will have more Lego blocks? Thus, there can be quite a variation in amount of energy transfer from the photon to the proton.
3. Deflection:
A photon will be deflected with the energy fields are pointing in opposite
directions. For example, every electron has an electrical field pointing
outward. Also, many protons have magnetic fields which loop through the
protons, like pearls on a necklace.
If the photon has its fields (electric or magnetic) facing the opposite direction upon approaching the proton, then the fields will be repelled, and the photon system will be deflected. The angle of deflection will depend on the angles at which the two fields touch each other. Note that in this case, there will be no energy loss for the photon. Only a change in direction.
4. Energy
Loss and Deflection: This situation typically occurs when the photon
brushes or glides against the fields of the proton, and these are in the same
direction, but only partially brushing of the photon to the proton. This means
that only the energy strings furthest from the photon core will attach to the
proton, while the rest of the photon system goes on its way.
The
“deflection” then occurs because there is a slight tug of the merged energy
strings before the photon system breaks away, goes on its way again. The effect
is similar to the bending of light around a star; that is, a slight change in
angle, but not much.
Multiple
Particles in a Liquid Molecule
Another
complicating factor is the various particles in a molecule. We have electrons
and protons, each of which can absorb photons. We also have molecular electrons
of the molecular bond, which are slightly different from the electrons of the
individual atoms. Let us look at some of these.
1. Electrons orbiting an atom
Photons
can be easily absorbed into electrons. The photon core is small enough to fly
through the holes of the surface of the electron. If the photon approaches the
electron away from the field, then there will be no repulsion, and the photon
will easily be absorbed.
In
contrast, if the photon approaches the electron at the location of the
electron’s electrical field, and when electrical fields of each are pointing
opposite direction, then the two fields will repel. This will cause deflection
of the photon. The angle of deflection will depend on the angle when the two
fields meet.
Electrons
also have magnetic energy. This magnetic energy can extend from the electron to
the space beyond. If the photon approaches this magnetic field in opposite
directions, then again the photon will repel, and be deflected.
However,
if the photon manages to glance by the electron, at either the electric or
magnetic fields, and the fields of both particles are in the same
direction…then this will result in partial energy transfer, and likely a slight
deflection of the photon.
2. Protons in an atom
A
photon can enter a proton more easily than in an electron, as the entrance
holes of the protons and neutrons are much bigger than the electron.
Furthermore, the electric field of the proton flows inward, not outward. This
means that the photon will never be electrically repelled.
There
are several options here. If the photon reaches the proton away from the proton’s
electrical field, then the photon will simply dive into the hole. This is
complete absorption.
The photon can
also be partially absorbed. This will happen when the magnetic fields of the
photon and of the proton are pointing in the same direction. Some of the
magnetic energy of the photon will leave the photon for that of the proton, and
the photon will go on its way, with slightly less EM energy (and lower
frequency).
3. Electrons of the Molecular Bond
The electrons
of the Molecular Bond deserve special attention. They have the characteristics
of regular electrons…plus more. Photons of many frequency can be deflected, and
partially absorbed. However, to be fully absorbed requires that the photon’s
pulsation frequency match the molecular orbital frequency.
The
frequencies must be identical. And, the photon must arrive at just the right
time, for the fields of all three to match, in order to be fully absorbed.
Full
Absorption of Photon System in a Molecular Bond
In other
publications I have discussed my model for the molecular orbits. Let us review
that model briefly. In this model, the molecular orbit is like a race track,
oval in shape, with two cars driving.
The molecular
orbit therefore consists of an oval track, along which two electrons travel.
From the side, we see two parallel tracks, with each electron seeming to travel
in opposite directions. When the electrons approach each other, on their
parallel tracks, this is when the molecular bond contracts. When the electrons
move away from each other, on their parallel tracks, this is when the molecular
bond expands. This process, therefore, is the physical cause of contraction and
expansion, repeatedly.
In other
words, this process is the “vibration” of the molecular bond. The rate of this
repeated action is the “frequency” of the molecular bond.
Therefore, in
order for a photon to fully be absorbed by the “molecular bond”, and not just
individual electrons, the frequency of the photon must be identical to the
frequency of this race track expansion-contraction vibration.
The photon
must also arrive at just the right moment…where the fields of both electrons,
and of the photon, align perfectly. The energies of the EM system will then be
split up…some of the energies in one electron, and some of the energies in the
other electron.
*The two
electrons may in fact be energetically linked… with magnetic energy strings and
electric energy strings connecting the two electrons*.
The photon
core may be absorbed in one of the electrons. However, I think it more likely
that the photon core is held between the two electrons, as they race around the
track.
I am still
working out the details. However some things are clear. In order to be fully
absorbed in a molecular bond:
a. The
Frequency of the Photon System must be the Same Frequency as the electrons
going around the race track loop.
b. Both
electrons must absorb some of the energies of the photon - of that one photon
system, at the same time.
c. The Photon
System must arrive at the exact time, with the moment of pulsation, such that
this total absorption of energies in both electrons is possible.
Summary
of Electromagnetic Energy Traveling Through Liquids
In this
chapter we looked at how Electromagnetic Energy travel through liquids, such as
water.
Liquid molecules
are constantly in motion. They move individually and in groups. They tumble,
roll, and migrate. The photon system is a photon core, with energy strings as
passengers.
This photon
system normally travels at fast speeds. However, due to the all the liquid
molecules in the way, the photon is blocked and bumped into. Therefore it takes
longer for the photon system to travel through the water than normal.
Notice it is
not that the photon has slowed down. Rather, the photon just takes longer to
get past all the obstacles. Indeed, when the photon exits the water, we see the
photon return to its normal fast speed, as there are fewer obstacles in the
way.
The photon is
very small compared to the molecules, which allows the photon to travel between
the spaces between the molecules. However, the molecules are constantly
tumbling and in motion. This means that any photon entering water will likely
be hit by molecules, and often multiple times.
There are
several options which can occur. The most common include: 1) total absorption,
2) partial absorption of energies and slight deflection, 3) deflection without
any loss of energy.
Which option
will occur must depend on a variety of factors. The most important of these are
a) the alignments of the energy fields, and b) the angle at which these fields
touch.
Other factors
include: c) the specific frequency of the EM pulsation, d) the internal energy
of the atomic particle, and e) frequency matching.
These are the
main options, and how they occur. Note that this is just an overview. There are
additional factors to consider, and details to be discussed. These will be examined
in future chapters and books.
