We
introduced the xenosubstance (XS)
as being an unstructured, perfect continuous
substance. But so is vacuum (V). It
is clear that we need to add additional
properties of characterization for xenosubstance
if we hope to advance further and, it is also
clear that ultimately xenosubstance is nothing
more nor less than the reincarnation of the old
and troubled concept
--the æther, the prevailing
substance that was assumed to occupy the entire
cosmic space of the Universe. That such a
substance must exist was indisputable for
centuries as the necessary medium for
propagation of all material perturbances. To
abolish the existence of a material medium
prevailing throughout the space of the Universe
and substitute it with vacuum (as it is done in
Einstein's Theory of Special Relativity and in
the subsequent so-called "modern" Physics) is an
absurdity of truly "cosmic" proportion as no
material perturbation could possibly travel
through vacuum.
Isaac
Newton reflecting upon this very subject noted,
in no uncertain terms, the tremendous absurdity
of considering vacuum as the prevailing entity
filling up the space of the Universe. In his
letter to his friend Richard Bentley, Newton
wrote:
"...
that one body may act upon another at a
distance through a vacuum, without the
mediation of any thing else, by and through
which their action and force may be conveyed
from one to another, is to me so great an
absurdity, that I believe no man, who has in
philosophical matters a competent faculty of
thinking, can ever fall into it."
[Isaac Newton's Principia, vol. II,
University of California Press, 1966, p.
634].
Now,
that we re-introduced the æther substance
through a new name --the xenosubstance (XS), let
us define this xenosubstance through its
intrinsic properties of
characterization:
I.
First, we shall assume that XS is a perfect
continuous elastic substance (within the meaning
of Continuum Mechanics) which, when
unconstrained, is assumed to reside at its
lowest possible density, say 
.
We call this natural state of existence XS its
xenobase state (XB).
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We
introduced the primeval admixture of
Nature as being made of
xenosubstance (XS) and
vacuum (V). Now with the
recognition that the natural state
of existence of XS is
xenobase (XB), it follows
that
the primeval admixture of Nature
is made of xenobase (XB) and
vacuum (V).
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This
bottom-line admixture (of xenobase
and vacuum) must act as the primeval
"base" of Nature and, as such, that
base must reflect an inner unity
through an existing intrinsic bond
between them.
We
call that bond, the xenobasebond.
We express this intrinsic bond
or alliance of the primeval
admixture of Nature
through
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The
Third Fundamental Principle
of
Nature:
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In
Nature, xenobase and vacuum
are integrated into one
non-stretchable foundation
that cannot be pulled
apart.
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REMARK-1: The Third Fundamental
Principle of Nature states that
there is a fundamental alliance at
the base-level of Nature that cannot
be broken or separated one from
another.
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REMARK-2:
In simple terms, the xenobasebond
propriety of XB states that a
XB-block in the vacuum space cannot
be pulled out from that space as
--by the xenobasebond property-- the
XB-block cannot be separated from
its vacuum environment.
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Now
that we have recognized through The Third
Fundamental Principle of Nature, of the
indestructible bond that exists between
xenobase (XB) and vacuum (V), we need
to see what are their respective proprieties of
characterizations and as such, let us begin with
this line of exploration.
We
will consider the XB state to be characterized
by these properties:
1.
XB (i.e., XS in the XB
state) opposes no resistance towards
compression. We call this the non-compress
resistivity property.
2.
XB (i.e., XS in the XB
state), up to a finite upper limit, will
resist to be stretched or decompressed. We
call this the non-stretch property of
XB.
 The
xenobase critical resist
force is the maximum
stretching force that can be
applied on XB without
being broken apart.
When
XB is being pulled apart
(in an attempt to be stretched),
the energy of the pull is being
transmitted into the XB
state transforming XB
state into a tensioned XB
(tXB) state. Unlike a
normal XB (nXB) state, a
tensioned XB (tXB)
state will oppose resistance
towards compression, the "power"
of this ressistance being equal
(but opposite) to the force of
the pull. As soon as the force of
the pull is being removed, the
tensioned XB state (by
having no mechanism of keeping
its acquired tensional
energy) transforms back into
its normal XB (nXB)
state since, as stated, the
XB state has no capacity
of keeping the infused energy
transmitted through the
pull.
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REMARK:
Towards compression, XB
behave exactly as a perfectly
elastic body. On the other
hand, towards decompression
XB acts as an absolute
rigid object.
.2-a)
This remarkable dual
diametral opposite behaviour
and property of
characterization of XB
is called the
xenobase flip
property of XB.
.2-b)
The ability of the
XB-state to completely
be flexible towards
compression and be absolute
inflexible towards
decompression is called the
uniflex property
of XB.
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II.
XB, through a body-force of
compression or squeeze, by being
infused with compressional energy (derived from
the squeezing force) and, by being a perfect
elastic medium, will transform into a
"condensed" state called the xenofluid
state (XF) that is characterized by
these properties:
1.
XF, by not having an inner "mechanism"
of keeping or storing the acquired
compressional energy, will have the natural
tendency of releasing its acquired energy and
transforming back to its original XB
state of existence. We call this natural
property of XF its xenormalization
property. The force and the field
emanated through the xenormalization property
is called the xenoexpand force FE
and xenoexpand background
field 
,
respectively and the law expressing the
xenormalization property of XF is
called the DownState Law (DSL). In
essence, this law states that the xenoexpand
force FE is proportional to the
density 
of XF that was acquired from the
compression of XB, the greater the
density the greater the magnitude of this
force (being zero at the XB state). We
can write this as follows:
2.
Because of the DSL, it follows that XF will
have a resistivity towards further
compression that will be equal in magnitude
to the FE. If we call the
resistivity force towards further compression
the xenoresist force FR,
then the two forces FE and
FR are equal (but opposite) in
magnitude,
|FE|
= |FR|
III.
We call xenogel (XG), a
denser XF than its eXF. XG state
may be viewed as a "crest" of eXF and be
called xenocrest.
1.
A XG "body" cannot be removed from its
eXF being an integrant part of it. This is
xenobond propriety of
XG.
IV.
By the First Fundamental Principle of Nature,
XF cannot accommodate an indefinite
compression as it will exist a maximum value
density, called critical density
,
beyond which the XF state can no longer
sustain compression. We call this new, maximum
density state of existence of XS as the
xenorigid (XR) state whose
properties of characterization are as follows:
1.
XR has no capacity for additional
compression --the so-called xenoresist
property of XR.
2.
XR cannot be penetrated but it can be
bent as XR by having no opposition
toward decompression would allow the incoming
force to bend the surface of XR transforming
that part from XR into XF. We call
this xenomalleability property of
XR.
3.
A XR "body" cannot hold the xenobond
propriety with its environment. We call this
the xenodisconnect property of XR.
A XR object can be removed from
its environmental xenofluid-space as all its
bonds with XF-environment have been severed.
All
states of existence of xenosubstance (XS) above
the xenobase state (XB-state) were
introduced as a result of some unspecified
global compression and the study of the origin
of those compressions at the primeval
Level of Organization of
Matter (LOM) is essential into gaining
additional insight of primeval LOM. In this
regard, how xenofluid (XF) is being produced in
Nature is of paramount importance --this being
our first step upwards in our long and
unprecedented journey.
But
before entering into the study of the formation
of the xenofluid-state in Nature, in our next
section, we will turn our attention to the other
PIN (primary ingredient of
Nature) --the vacuum
(V).
