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Re: Magnetic Fields Weave Rings Around Stars


On July 12, 2001, Ron Baalke writing for NASA et al wrote in
Article <9ikjcs$5th$1@nntp1.jpl.nasa.gov>:

> Space Telescope Science Institute, Baltimore, MD
> University of Hamburg, Germany
>
> There are stars with planets. Stars with companion stars.
> Stars with pancake-shaped disks of rocky debris. But how
> about young, hot, hefty stars embedded in large inner
> tube-shaped clouds of shimmering gas? Astronomers had
> suspected that the thick rings are the signatures of stars
> with strong magnetic fields. .... The team also suggests
> that rings around massive stars are more common than
> scientists thought. The study shows that magnetic stars
> with normal chemical abundances can have rings, too.

That’s what the Zetas just SAID!  Electromagnetic fields can be immense,
and man underestimates their size!
On July 11, 2001, Nancy Lieder, writing for the Zetas, said in
Article <3B4CB742.F51EC003@zetatalk.com> under thread
Re: Has Ball Lightning been Explained?

>   As we have explained, there is a sub-atomic particle
>   responsible for the magnetic behavior of certain
>   metals like iron.  This flows from and through those
>   atoms that have an uneven distribution of electrons
>   circling around the core, so the field developes around
>   a single atom but the flow of this particle causes them
>   all to line up in liquid iron so as a group they have a
>   field where the flow of particles leaves one end of the
>   field and warps around to the place where they are
>   LEAST, Nature abhoring a vacumn of any type. ...
>
>   Consider that an electrically charged field may be
>   IMMENSE, covering the horizon that can be seem
>   from end to end, and rising for miles up into the sky.
>   Consider that within this charged field, there are
>   not simply electrons and the particle that creates the
>   phenomenon of magnetism, but all the other 387
>   particles that operate in a similar manner, each with
>   its own desire to equalize its distribution in the
>   vicinity.  Ball formation occurs when the particles
>   that would disburse are FORCED to remain in the
>   vicinity by a GREATER pressure from other
>   particles surrounding them.
>       ZetaTalk™