A
vacuum-volume is being defined as a
volume that does not contain (i.e., is
devoid of) xenosubstance (XS).
A
xenovoid-volume is being defined as a
volume that contain only xenobase (XB)
or only xenofluid (XF). If the
xenovoid is made up of only XB, we
call it a hard xenovoid and, if
it is composed of only XF (with or
without xenogel XG) it is called
soft xenovoid.
A
xenofill-volume is being defined as a
soft xenovoid with xenorigid (XR)
substance in it.
1.
Vacuum (as is for xenosubstance) cannot be
created by any means. This is a
straightforward consequence of the
Second Fundamental
Principle of
Nature
that
states that no primary ingredient of Nature
can be made out of anything or by any
means.
2-3.
Vacuum cannot be stretched or expanded. This
is the non-stretch property of vacuum
that is similar to the property of xenobase
(XB).
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PASS
WITH
CARE
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REMARK:
One may resist accepting this
property on the rationale that there
is nothing in vacuum that can oppose
resistance to anything!
Well, let's then
assume that a vacuum volume can be
stretched. Then, the force (or
better the work) responsible for the
stretch has been transformed into
creating new vacuum, an absurdity of
course and in direct violation of
the Second Fundamental
Principle of
Nature.
 Fundamental
Remark
On the Vacuum Symbiosis
with
Xenosubstance
The
Third Fundamental Principle
of
Nature
establishes the existence
of an intrinsic bond,
called the xenobasebond,
between vacuum and
xenobase. As also noted,
that xenobasebond is being
transmitted to the
xenofluid state but not to
the xenorigid state.
Now,
in order to stretch
something, we need to be
able to hold on its
extremities. For vacuum to
be stretched, that vacuum
therefore must be enclosed
into a surface made of
xenofluid. The non-stretch
property of vacuum states
that XF-surface that
encloses the vacuum cannot
be stretched or expanded.
A
straightforward consequence
of the non-stretch property
of vacuum is that for
xenobase or xenofluid
surfaces in contact, vacuum
could act as a sealant that
is the xenosealant
property of
vacuum.
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4.
A XS-block (be it in the XB, XF, or
XR state) entering into a vacuum space
will shear the vacuum space without
resistance. A XS-block spinning in a
vacuum-space will also shear the vacuum space
without resistance. We call this the
shear-free property of vacuum.
5-6.
Vacuum (as XB) opposes no resistance
towards compression. Vacuum's remarkable
propriety of being able, without resistance,
be compressed, but impossible to be
decompressed is called the uniflex
property of vacuum. The same uniflex
property holds for the xenobase
(XB).
REMARK:
When compressed, vacuum remains
the same vacuum. There is no such
thing as a "condensed" vacuum. We
call this preservation property
of vacuum its xenohold
property. A "compressed'
vacuum cannot be decompressed.
This rather strange irreversible
process of vacuum is at the
substratum of its uniflex
property.
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7.
Vacuum cannot be compressed until it
completely disappear. The Second Fundamental
Principle of
Nature
would
not allow this to happen.
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PASS
WITH
CARE
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One
may ask: if we have say two (2)
parallel plates of XR in
vacuum moving towards each other,
they eventually will collide one
into another eliminating all the
vacuum that existed between them.
How then this squares with the
statement above that vacuum cannot
be completely eliminated from a
given extent?
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Well,
a vacuum surface will remain between
the two plates. This vacuum-surface
is a vacuum-singularity that cannot
disappear.
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In
Nature, we have vacuum-point
singularities, vacuum-line
singularities, and vacuum-surface
singularities.
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These
vacuum-singularities mirror the
singularities employed in
Mathematics: point, line, and
surface.
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REMARK:
Vacuum-singularities between
xenofluid surfaces act as absolute
sealants, i.e., they are
xenosealants.
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