Article: <5dcq9j$5us@dfw-ixnews6.ix.netcom.com>
From: saquo@ix.netcom.com(Nancy )
Subject: Re: ENERGY WAVES - the Zetas Explain
Date: 6 Feb 1997 14:36:35 GMT
>> (Begin ZetaTalk[TM])
>> In the last few centuries, mankind has moved:
>> 3. to thinking of matter and energy being composed of
the
>> same substances - subatomic particles.
>
> Not quite. Subatomic particles *have* energy, and energy
> and matter are interchangeable (E=mc^2).
> ynecgan@cmc.doe.ca (Greg Neill)
(Begin ZetaTalk[TM])
If you are saying that a matter OF A PARTICULAR TYPE might be
considered energy when on the move, or as you say, having energy,
but be considered a solid when stationary, then we are in
agreement.
(End ZetaTalk[TM])
In article <5d2dlf$i5f@pollux.cmc.doe.ca> Greb Neill
writes:
>> In discussions of subatomic particle movement, an
analogy
>> to the behavior of liquids might help humans relate.
>> Humans are aware that water can appear to be a solid,
>> when ice, or on the move, when a liquid. They are also
>> aware that water can take up less space when cold and
>> more when warm, having what is called heat energy
>> stuffed into the same space.
>
> As a matter of fact, Nance, water can take up *more*
> space when cold (ice) than when warm (liquid water).
> ynecgan@cmc.doe.ca (Greg Neill)
(Begin ZetaTalk[TM])
In our statement above we did not list every possible state of
water, for instance leaving out steam or cloud formations or
humidity or situations where water is below the freezing
temperature but still liquid due to rapid motion as occurs in
rivers during winter. Warm water requires more space than cold
water, when in the liquid state. The issue of expansion at the
point when water turns to ice in fact supports our explanation,
though this is not immediately apparent. We will explain.
Humans are aware that during molecular changes, rapid expansion can and does occur. Explosions are such a situation. Subatomic particles bound closely to the nucleus of atoms go on the move, and bump each other during this activity, so the exploding mass as a whole requires more space. There is pressure outward. But explosions seem to be accompanied by heat, where the formation of ice crystals seems to be due to the lack of heat. So why would ice crystals expand, requiring greater space than the liquid state just before? Gaze at a drop of water and the same water molecules represented as fluffy snow. Snow, as the weary crews that plow roads in winter are painfully aware, takes up so very much more space. Several feet of snow, when melting in the winter, end up representing only a few inches of rainwater.
Heat is composed of several subatomic particles that act as a lubricant for molecular motion, where atoms change their position with respect to one another. Thus, as is well known by humans, hot metal or rock can become liquid. The lack of heat particles creates a situation at a certain point where atoms are pressed against each other, and a different drama ensues. Just as within explosions, where subatomic particles on the move require MORE space than in the prior, pre-explosive state, just so the near proximity of other atoms can create this need for more space. The loss of heat does not necessarily accompany this expansion, as the processes are separate though often occur simultaneously. In the case of ice formation, there IS a steady lose of heat during the freezing process, however, so to some degree one might call the formation of ice a controlled explosion.
What occurs at the point that freezing water turns to ice is
that subatomic particles trapped within each water particle are
encouraged to move into areas FORMERLY OCCUPIED BY HEAT. Like
children under a teacher's thumb while at their desks, when the
teachers are elsewhere, they scamper out into the halls to play.
They no longer bump into heat particles flowing between atoms
when the normal course of their movement within the water atoms
brings them to the periphery. Just as in an explosion, where the
rearrangement of particles at the atomic level requires more
space, just so the quiet explosion that freezing water represents
requires more space. The water atoms are now increasingly SHARING
subatomic particles, which move to the periphery of an atom and
loop through and around other atoms before returning. Thus the
atoms become bound to each other by the wash of this motion, and
become static ice!
(End ZetaTalk[TM])