I just glanced at that post and saw the reference to black opps and
such, so discounted it, but now that you bring it up, a reality check is
in order.
You reposted;
> > The plasma, mercury based, is pressurized at 250,000 atmospheres at a
> > temperature of 150> <degrees Kelvin, and accelerated to 50,000 rpm to
> > create a super-conductive plasma with the> <resulting gravity
> > disruption.>
Then commented;
> I'm still waiting for someone to explain how the mercury could be a
> plasma at that temperature and pressure.
The conversions are;
250,000 atmospheres X 14.7 psi (which is 1 atmosphere) = 3,675,000 psi
150 degrees Kelvin equals -189.67 Fahrenheit
How can there be a super cold plasma, when the mercury is both cold and
compressed? hmmm, a cold plasma...
Ionize the mercury to form a hot plasma vapor, like in the mercury lamps
that light our parking lots. Ok, I'll buy that.
Now if the particles of mercury vapor were to be compressed at such an
amazing pressure, which I don't think has been remotely achieved, that
should force the particles closer together which would only remain
separated by adding additional electrical energy to keep it electrically
excited and repellent from each other. So that could be possible but I
still question the pressure...
Ok, now to supercool the whole thing down which could make it
superconducting.
Maybe, if this was possible, the sequence is critical, I used the
formation of the plasma first since something has to make the vapor and
keep the particles spaced apart. The reason being that compression and
cooling would cause the particles to blend into a solid, thus losing the
plasma condition.
Ah well, the numbers are pretty far out as is the claim..
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