Sub Quantum Chromodynamics SQCD
Introduction;
Quantum chromodynamics, familiarly called QCD, is the modern theory of the strong interaction. Historically its roots are in nuclear physics and the description of ordinary matter--understanding what protons and neutrons are and how they interact.
In the same pictorial language, QCD appears as an expanded version of QED. Whereas in QED there is just one kind of charge, QCD has three different kinds of charge, labeled by "color." Avoiding chauvinism, we might choose red, green, and blue. But, of course, the color charges of QCD have nothing to do with physical colors. Rather, they have properties analogous to electric charge. In particular, the color charges are conserved in all physical processes, and there are photon-like massless particles, called color gluons, that respond in appropriate ways to the presence or motion of color charge, very similar to the way photons respond to electric charge.
Quarks and gluons
One class of particles that carry color charge are the quarks. We know of six different kinds, or "flavors," of quarks--denoted u, d, s, c, b, and t, for: up, down, strange, charmed, bottom, and top. Of these, only u and d quarks play a significant role in the structure of ordinary matter. The other, much heavier quarks are all unstable. A quark of any one of the six flavors can also carry a unit of any of the three color charges. Although the different quark flavors all have different masses, the theory is perfectly symmetrical with respect to the three colors.
For all their similarities, however, there are a few crucial differences between QCD and QED. First of all, the response of gluons to color charge, as measured by the QCD coupling constant, is much more vigorous than the response of photons to electric charge. Second, as shown in the box, in addition to just responding to color charge, gluons can also change one color charge into another. All possible changes of this kind are allowed, and yet color charge is conserved. So the gluons themselves must be able to carry unbalanced color charges. For example, if absorption of a gluon changes a blue quark into a red quark, then the gluon itself must have carried one unit of red charge and minus one unit of blue charge.
Sub Quantum Chromodynamics
What means sub quantum chromodynamic?
The fundamental particles of the universe that physicists have identified - photon, electron, neutrino, quark and so on, are the letters of all matter. Just like their linguistic counterparts, they appear to have no further internal substructure. CPH theory proclaims otherwise. According to CPH theory, if we could examine these particles with greater precision beyond our present technological capacity, We would find that each is not point-like but, instead consists of a tiny particles containing a lot of sub-quanta field particle that is moving, oscillating, dancing that calls CPH (Creation Particle Higgs).
Everythings such as photons are formed of CPH. An electromagnetic wave is moving with two different fields (electric field and magnetic field) that have two different properties. These fields contaion a lots of tiny particles that are able to form electric field and magnetic field. But, these particles are so small that cannot appear like a charge particle or a magnet, and they called color charge and color maget. So, these tiny particles are Sub Quantum Chromodynamics.
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Sincerely
Hossein Javadi
Yahoo CPH Group