Summary of Quark Forces

This page summarizes the equal force principle that holds the three quarks together while at the same time holding the three quarks apart.

The Cosmic Matrix Displacement model is a theory that helps guide our imagination about the underlying dynamics related to forces and particles. The CMD generates a clear picture of what actually takes place on the quark level. The current scientific explanation of the strong force is that gluons are the exchange particles that increase or decrease the “attractive force” between quarks. The CMD shows that there is no such thing as an attractive force, and that inward and outward balancing forces between quarks are the result of displaced VS1’s in the Cosmic Matrix pushing the quarks together and the outward interference wavepoints from a pair of quarks pushing the other quark away. If you try to pull two quarks apart by adding energy to the hadron, the quarks’ rotational velocity is increased. The quarks are striking more VS1’s, transferring more energy inward, and the quarks are moved back toward their normal orbits. As the quarks move inward, they are spinning faster and generating stronger interference wavepoints that move the quarks apart to their normal orbits. Within the hadron, the quarks move around freely and easily.

Scientists suspect that they will never be able to generate enough energy in a collider to study free quarks. The CMD model indicates that quarks might be separated by positioning artificial gravity generators in strategic locations around a confined hadron sample that would “disrupt” the VS1 vector lines of force which hold the quarks together, and allow the outward moving interference wavepoints to spring free quarks into the test area.

The Cosmic Matrix Displacement model (CMD) explains the three basic forces (or interactions) from a different perspective than the quantum field theory. The brief CMD description of each is as follows:

The Strong Displacement Gravity Force (or interaction)
(see pages 12, 13, 14 and 15 for full explanation)

The strong (DG) force acts between quarks in protons and neutrons to hold them apart and together, resulting in a balanced system that prevents quark separation. The strong (DG) force also extends across the nucleus holding protons and neutrons together to form nuclei.

The Electroweak Displacement Gravity Force (or interaction)
The CMD shows that the electroweak DG force does not actually mediate the conversion of certain particles into other particles. The VS1’s in the Cosmic Matrix act on high-energy particles to slow them down and change them into other particles. The VS1 energy is a displacement gravity force that is misinterpreted as the electroweak force. Radioactive decay is the result of VS1 displacement in the Cosmic Matrix.

All of the current high-energy particles are very short lived, and break down into electron interference wavepoints or photon waves. The CMD shows that all of these particles are high-energy variations of a wavepoint or a photon wave. THEY ARE NOT SEPARATE PARTICLES.

The CMD shows that all waves and interference wavepoints are generated from the quark clusters of protons and neutrons. There is only one force on the subatomic level that the CMD defines as Displacement Gravity.

The CMD explains how the mass of a body increases (and decreases). There are two meanings for mass in general relativity. The first meaning is “relativistic mass” and is defined by stating that the mass of a body increases with “velocity”. The second meaning is “invariant mass” and is defined by stating that the mass of a body increases with the “energy content” of the body. The CMD shows that as the inertial velocity of a body (of atomic matter) increases, there are more VS1’s in the Cosmic Matrix rebounding off the body as the velocity continues to increase. As a result, there is more energy transfer from the VS1’s to the body of atomic matter and the relativistic mass increases. Einstein clearly states: E=mc². This formula can be taken to include kinetic energy (or the rest frame for invariant mass). The CMD shows that when velocity increases to a value approaching the speed of light, the energy transfer from the VS1’s is so great that there is no way to generate enough “added energy” to further increase the velocity. When the invariant mass of a body increases, the increased energy from the VS1’s increases the angular momentum of the body. (In other words, the quon spins faster.) The faster spin rate moves the VS2’s in the quon cluster to larger orbits and a slower rotation velocity. As a result, the quon’s relative time slows down compared to the other quons that have not been accelerated.

When the body (of atomic matter) is slowed by an outside energy source, the cluster of VS2’s (in the quon) speed up, then drop back to their normal orbits and normal relative time.

The CMD explains how atoms can make transitions between orbits, allowed by quantum mechanics and as first proposed by Niels Bohr. The quantized energy levels of the hydrogen atom, (as an example), shows that atomic excitation by absorption of a photon increases the angular momentum of the quarks in the proton. The curved nature of a photon wave moves each quark to a larger orbit as the wave passes through the proton (or quark cluster). Just as a “curved region” of VS1’s generates a gravitational field (see page 2-3), a “curved” moving light wave (or photon) creates a momentary curved region of VS1’s that moves the quarks to larger orbits as it passes through the quark cluster. The quarks sustain their orbital velocity by “inertial angular momentum” (see page 12). The photon wave adds energy to the quark orbits by moving them outward. The outward motion adds to the angular momentum of each quark in the cluster. When the quarks spin out to their new (temporary) orbits, they instantly move VS1’s and generate a new wave in the surrounding VS1’s that has exactly the same energy and frequency as the original photon wave that passed through the proton (or quark cluster). The new photon wave is regenerated (see page 22) out through the VS1’s to produce atomic excitation in another atom. As the quarks in the hydrogen proton move back to the normal ground state, their orbits return to normal. This is called atomic de-excitation and is repeated over and over, generating the reflected light wave images we see all around us.
The CMD also gives us a new image for the basic wave profiles of Leptons and Bosons. The only difference between profiles is the number of VS1’s that are actively moving in the waveshape, the number of interference wavepoints in each wave, and the combinations of waves emerging from the quark clusters that generate them.

The basic waveshapes are as follows:

1) The Neutrino Waveshape <<< click for larger image

[ The neutrino waveshape (shown above) has very few interference wavepoints and very few interactions with other matter. It is a very weak wavshape and very stable. ]
The neutrino waveshape is so weak it can pass through any object without interacting. It has very few interference wavepoints. Neutrinos are very stable and do not break down into other waveshapes. Neutrinos are generated by the two quarks in a neutron that do not generate the electron waves. They result from the spinout of the two quarks when a neutron changes to a proton and also from high-energy colliders. Antineutrinos are generated by neutrons rotating “opposite hand” to the neutrons generating neutrinos.

2) The Electron Waveshape <<< click for larger image

[ The electron waveshape (shown above) has a strong focused line of interference wavepoints.The electron waveshape is very interactive. A strong interference line of wavepoints give the electron a small amount of mass. ]
The electron waveshape is very stable and can move quons at the center of quarks. Free electron waveshapes are generated by the conversion of neutrons to protons. When the neutron spins out to the proton orbits, the quark that generates the waves of the electron cloud kicks off a free electron wavepoint before settling down to the task of generating the electron cloud wavepoint.

3) The Muon Waveshape <<<click for larger image
The muon is generated by high-energy collisions and is 207 times as massive as an electron and very unstable. It will break down in 1/500,000 of a second into an electron, neutrino and antineutrino, which together equal the same invariant mass as the original muon. The muon is composed of three waveshapes that are ejected from the neutron when it is struck by a proton generated by a collider. The neutron’s impact motion kicks off an electron antineutrino. The neutron breaks down and kicks off an electron and a neutrino. All three waves exit the neutron as they cross each other. In 1/500,000 of a second, the three waves clear each other and are detected independently by sensors.
It is important to note here that all high-energy leptons are manifestations of waveshapes generated by the three quarks in the protons and neutrons of the nucleus.

4) The Tauon Waveshape
The tauon waveshape is a very high-energy waveshape that is generated by colliders. The tauon breaks down into a muon in five trillionths of a second. The tauon’s high velocity accounts for its increased energy and large invariant mass. The tauon is generated by the quarks of protons and neutrons upon impact in a collider or high-energy breakdown of neutrons in similar collider environments.

5) The Pion Waveshape (this is a Meson)
This waveshape is very high energy and breaks down into a muon and antineutrino in one millionth of a billionth of a second. The pion is generated similar to the tauon.

6) The Neutral Pion Waveshape
The Neutral Pion Waveshapebreaks down into two gamma rays that are high-energy photons.

7) The Photon Waveshape (see page 22) <<< click for larger image
Electromagnetic radiation has a wavelength that could be 300,000 kilometers long, or as short as a trillionth of a trillionth of a centimeter long, and could be anything in between. Light waves travel through the Cosmic Matrix VS1’s (vortisphere one’s) at nearly 300,000 kilometers (186,290 miles) per second. When energy is added to atomic matter, the quarks, in protons of the atoms, speed up and jump into larger orbits, kicking off a photon into the VS1’s of the Cosmic Matrix that is the exact replica of the photon waveshape that added energy to the quark cluster. Some atom nuclei are composed of proton and neutron arrangements that absorb some or most of the photon wave passing through the nucleus. Atoms with low energy levels absorb the photon energy by spinning up the quarks into higher orbits. Photon waveshapes can have very high energy levels up to the ultraviolet range.
The CMD model shows that the VS1 nature of the Cosmic Matrix accounts for the wave-particle duality of quantum physics. Each VS1 that passes energy to the next VS1, and so on through the Matrix, is a wave point. The many VS1’s that are passing their excess energy along the waveface create the waveshape of the light wave. The VS1 structure of the Cosmic Matrix Universe is so incredibly responsive to the slightest stimuli, that a VS1 wavepoint can travel millions of light years from a distant star and still have enough energy to be visible to the human eye.

The Cosmic Matrix Displacement model (CMD) explains one aspect of quantum physics that scientists have struggled to understand: antimatter. The most common antimatter that nuclear colliders generate is the positron, or the counterpart to the electron. The positron is an electron that has “reoriented” its waveshape relative to other moving electrons.

<<< click for larger image In very high-energy environments, a very few electron waveshapes may reorient and collide with another electron in the same beam or in another target in a collider experiment. When this happens, the electron waveshape and the positron waveshape annihilate each other and generate two photon waveshapes that have the same combined energy at the original electron positron.

1 - 2 < larger image 3 < larger image 4 < larger image

8) The W or Z Boson Waveshape
I will not discuss the W or Z boson waveshape because they are created in a high-energy collider and break down in too brief a time to be detected. They are so short lived that they must be detected by their breakdown products of muons and neutrinos. The W and Z boson wavefronts are only variations of other wavefronts but have higher energy levels. They are not particles.

There is an interesting possibility to ponder here. The box to the left suggests that if you could build three gravity generators and position them around atomic matter with the correct orientation that weakens the interference points holding quons apart, the quark cluster disappears. Therefore, the proton disappears and the object disappears. WE HAVE CREATED AN ATOMIC DISINTEGRATOR. This is an interesting thought to ponder.