Contra Heisenberg
Sven Gelbhaar
20.5.2019
Uncertainty principle, also called Heisenberg uncertainty principle or
indeterminacy principle, statement, articulated (1927) by the German physicist
Werner Heisenberg, that the position and the velocity of an object cannot both
be measured exactly, at the same time, even in theory. The very concepts of
exact position and exact velocity together, in fact, have no meaning in nature.
— Encyclopedia Britannica, 20.5.2019
This principle is usually applied to very small things, such as photons and/or
electrons. Because of this, the vast sum of educated physicists think that
these particles don’t actually have a location and velocity and instead exist in
something called a ‘probability wave’. However, with the previous work in the
series, and now with consequences of Unified Force Theory, we can put this to
rest.
As discussed in previous papers, protons and electrons are attracted to one
another. This naturally results in a central proton, and because the charges of
protons and electrons are disproportionate to one another, the electrons cover
the surface of the proton via an equi-distant 3D matrix. How do we know this?
Quite simply: an electron microscope bounces electrons off protons to image
them. If there were no surface-electrons on these protons, there would be a
small ‘black hole’ instead of a visible proton, for as we know from every-day
experience, electrons only repel one another.
How does this play into the Heisenberg Uncertainty Principle? Surface-electrons
must necessarily be a self-sustaining matrix. Electrons are temporarily
displaced by this electron microscope, but there is only one stable
configuration for X amount of electrons to 1 proton: the central proton is at
the center, and the electrons — repelling each other — are equi-distant from
one another. As such it seems trivial to determine all of their locations and
velocities given but a few ‘images’ of the proton-electron complex. Further
research is of course warranted.