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Magnetic fields
A magnetic field consists of 2 composite parts.
1 A radiation field.
2 Spin of particles.
The universe's main system points to the fact that the
magnetic field consists of particle spind and radiation.
Until now,
I assess that the radiation is in a spectrum area with a
very large wavelength and is found in the radiation area
that has not been mapped so far.
The
radiation moves in a closed circuit. The most
probable thing is that the atom's base nuclei are
absorbed in the south pole and the energy is moved
through the base nuclei and emitted again in the north
pole.
If a change in the spin of the particles
occurs, there will also be a change in the wavelength.
That is, the wavelength is adapted to the spin and
energy of the particles.
I should note this
here: that radiation is a high velocity particle and we
have here another example of the particle properties of
the radiation.
Figure 951 shows a particle
rotating about its own shaft.
We have here a variant
of the velocity of the kinetic mass, with the inner part
standing still and the outer part having a velocity
maintained by the mass of the nucleus. It is comparable
to the deflection of the moon in the Earth's field of
attraction
You should be aware that the rotation
does not create any polarization of the magnetic field
but creates the deflection path of the radiation at a
certain wavelength.
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You should read my section on radiation.
The radiation is in the low-energy area with a large
wavelength.
I see no problems with magnetic
fields compared to the system I work with.
There
are some interesting things to do with polarization and
the core work of the inner work that are interesting to
look at.
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The
Universe.
Classic
big bang.
Mass
formation.
Atom
structure.
Atom
binding.
Molecular
binding.
Particle
radiation
Magnetic
fields.
Mass
attraction.
Conclusion.
Micro physics
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classic head physics