Quantum Mechanics and Wave Theory —
the Everything Theory
The eminent scientists Max Planck and
Albert Einstein opened the twentieth century with Quantum
Theory (1900) and the Theory of Relativity (1905), respectively.
Despite the fact that these men led two competing schools
of thought, they each had the highest regard for each other’s
work, as they sensed that their ideas shared a common fate.
Furthermore, although both men were confident that they were
heading down the right path, they realized that their theories
were still incomplete.
Wave Theory unites quantum mechanics and classical physics
by introducing a fundamental
structure that exists in all the universe’s elements:
one wave that is formed by two loops. This creation cannot
be simpler, but it is nonetheless ingenuous and highly sophisticated
as seen in the following classical example of the high-energy
photon (see illustration, right).
This formation shows that energetic matter is always composed
of a magnetic and energetic loop regardless of the phase (transition)
it happens to find itself in. These two
loops are one wave, one QUANTUM, or one whole wave in which
each of the loops constitutes only half of the wave formation
(this structure is also pervasive in the field of musicology,
see picture to the right).
In all phases, a wave’s behavior within this dual framework
is marked by change. The inability of physicists to develop
a theoretical basis with which to link between and satisfy
the classical and quantum schools stands at the heart of the
debate. However, the primary difference between these approaches
is that while classical physicists deal with wave formation,
quantum physicists are involved with subatomic particles.
Every subatomic contains only one loop and is merely part
of the greater loop, which itself is a component of the aforementioned
wave. Both Planck and Einstein felt uncomfortable with this
distinction, but despite their efforts they failed to resolve
this issue. Quantum mechanics, however, advanced ingenious
solutions that provide an explanation for the behavior of
The most prominent argument that has been raised against the
two camps is that while the rules of quantum mechanics work
for subatomic particles, they do not apply to larger formations.
Einstein and the classical physicists sought a universal equation
that would work for all facets of the universe’s creation.
Wave theory has indeed contributed one basic formation that
bridges the ideas of both camps and holds true for all that
exists in our universe — everything.