The Forces of Nature by Kelland Terry, Ph.D.
As explained in the previous blog, the atom’s electrons and quarks have the same string cycle frequency because the two subatomic particles are connected by elastic strings.
The oscillation frequency of the photons emitted by atoms during photon emission increases if the atom’s frequency of oscillation is raised. This means atoms not only emit visible light, as previously discussed, but other photons as well depending on the oscillation frequency of the atom. This makes it possible for a radio station transmitting antenna to emit radio wave photons with different frequencies. This is accomplished by controlling the oscillation frequency of the atoms with an electric current.
We might imagine that a quark spinning on its axis assimilates some of the proton’s elastic goo, which becomes available to be ejected as a photon. Ejection only takes place when the velocity of the quark is suddenly accelerated, which in turn rapidly increases its spin angular momentum. The faster the acceleration, the larger the mass ejected as a photon.
As explained previous, the photon ejected by a quark is captured by an electron in orbit about the proton. The electron moves to an outer orbit because of an increase in spin angular momentum. This is an unstable state and the electron emits this photon or one of less mass and moves to an inner orbit. In the case of the radio wave transmitter oscillating at low frequency, the photon emitted is a small radio wave.
It is likely that ejection takes place shortly after the beginning of the string cycle when the goo inside the quark is at its densest state and a new string cycle is commencing. At this point in time the conserved potential energy in the condensed goo is greatest.
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