The
precise mechanism of what's going on inside magnets is impossible to
know without detailed knowledge of their structure. However, there
are nevertheless quite a few things that can be said about magnets in
terms of the two orb Velcro model of photons.
What
we know about metals is that they are not random collections of
atoms. They are mega-structures. Treated the right way, they have
orientation, like crystals.
A
random zero-point photon finding its way into a magnet will find
atoms structured in such a way that there are quick ways out of it,
and lengthy ways out of it.
Bouncing
about inside a magnet, many zero-point photon will find the quick
exits. These are tunnels in the lattice going in the north-south
direction.
This
is not unique to magnets. All crystals have this feature, yet very
few crystals, if any, are magnets. So the presence of quick exit
routes do not in themselves explain magnets.
What
makes magnets special is that the walls of their tunnels are lined
with electrons that give the photons the required spin and direction
to form sustainable polarization. The more coordinated and vigorous
the electrons spin, the stronger is the magnet.
The
tunnels are necessarily uniformly lined with spinning electrons
throughout the metal, so photons come out spinning the same way
whichever end they come out of.
However,
they will come out with opposite direction. That means that the ones
coming out of the north pole spin opposite of the ones coming out of
the south pole, when viewed in the direction they are travelling.
Magnet
inducing spin into photons streaming out of the south and north
poles.
However,
viewed from the north, all photons coming out of the magnet spin with
their negative orbs rotating in a clockwise direction. This fact can
be derived from Ampère's right-hand grip rule, and also from how
current is induced into copper wires.
The
fact that photons come streaming out in equal measure from both ends
of a magnet tells us that there must be a lot of tunnels going
through the metal, and that they must have entry points as well as
exit points at the poles. Otherwise, there would be a permanent
photon over-pressure at the poles and a corresponding under-pressure
at the sides. This would violate the laws of thermodynamics, and is
obviously not happening since it would produce a noticeable wind.
The
way magnets allow for incoming photons at the poles is by setting
them spinning in the same direction as the outgoing photons.
When
outgoing photons meet incoming photons, they brush into them, sharing
some of their spin. This polarize the incoming photons as they head
towards the magnet. Even before they enter the magnet, they have a
certain degree of polarization.
Photons
entering and leaving both ends of a magnet.
Note
that spin is transferred between opposite charge orbs. Like charge
orbs do not react with each other since they cannot latch onto each
other. Negative orbs communicate their spin to positive orbs and visa
versa. The fact that the negative and positive orbs spin in opposite
direction to each other allows for spin to be maintained and shared.
The
sharing of spin from outgoing to incoming photons produces a pattern
in which highly polarized outgoing photons are surrounded by
progressively less polarized photons. Between each highly polarized
outgoing photon, there is a valley, so to speak, of less polarized
photons.
Interestingly
enough, it is in fact possible to observe this pattern.
When
a ferrofluid is placed on top of a magnet, it morphs into sharp peaks
surrounded by shallow valleys. Highly polarized outgoing photons are
producing the peaks, while less polarized incoming photons are
producing the valleys.
Ferrofluid
By
Steve Jurvetson - http://www.flickr.com/photos/jurvetson/136481113/,
CC BY 2.0, https://commons.wikimedia.org/w/index.php?curid=906519
No comments:
Post a Comment