©Kyle Vincent Schiefer and "Quark and Kytons" blog, 2014. Unauthorized use and/or duplication of this material, to include derivation of, but not limited to, proposed technologies and/or commercial plans without express and written permission from this blog’s author and owner is strictly prohibited. Excerpts and links may be used, provided that full and clear credit is given to Kyle Vincent Schiefer and "Quarks and Kytons" with appropriate and specific direction to the original content.
Within the constraints of the Kytonic Theory of the universe, all energy in the universe is, by its nature, imbalanced, and dominated by either a positive or negative motional charge. The resulting drive-state of imbalanced energy clusters act like magnets as the kytonic bodies are attracted and repelled by relative bodies as they seek to combine and mix with similarly opposed charges in an attempt to regain true terminal neutrality.
As kytonic bodies repeatedly impact with opposing charges, groups can become charge-heavy with excess energy that can ultimately cause a motional "wobble" that can to do more harm than good to the energy cluster; especially in an opposing-charge atmosphere. This happens specifically when the drive charge of the body in question becomes twice as strong as the passenger, resulting in a >2/3 imbalance. This can also happen if the drive charge becomes outweighed by the passenger should it become <1/2 of the total charge amount in a relative atmosphere. When this happens, an increased imbalance occurs that immediately begins to correct itself accordingly by driving to, or pulling in, the energy it now needs to correct itself. Simultaneously, the cluster will begin radiating the excess charge that has become heavy with in order to further strive for balance.
As these radiation energies are released, they will exhibit relative effects and one of three wave forms that correspond to its dominant charge as interacting with an opposing atmosphere. motional state of its dominant charge, but will react differently in subsequent impacts due to the heavy one-sided charge relationship. These radiation energies will exhibit a natural state of decay as it drives to rectify it's imbalance by being absorbed by, or otherwise combined with other kytonic bodies in it's surroundings under the conditions of relative atmospherics. Depending on the dominant charge of these energies, the three radiation states are as follows:
- Positive-dominant (Heat Waves/Infrared Radiation)
- Negative-dominant (Light Waves/Gamma Radiation)
- Neutral-Dominant (Magnetic Waves/X-Radiation)
For example, imagine that in the vast void of space (negative dominant atmosphere), there existed a near-balanced star that held a net charge of -1 : +2. Now imagine that a radiation impact resulted in the net charge change that caused the star's core to become +5 : -2. the resulting spin charge would create a semi-stationary gravitational singularity that would both gravitationally attract (since it can't readily move) as much negative energy as possible, while simultaneously radiating as much excess positive energy as possible in order to regain a manageable balance. This type of event would result in a black hole that would appear to spit out more energy than it pulled in.
So how is this relevant?
Understanding the fundamental relationship of kytonic impacts yield two crucial pieces of information; motional states occur when clusters of positive and negative energy impact with each other in relative atmospheres, and that
If we could replicate this consumption/radiation effect by altering the relative motional states of objects (spin = relative positive/ vector = relative negative)
****This blog entry is incomplete and has been a "draft" for months, but still bears publishing****
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