The velocity of the electron in orbit about the proton is 2 x 10^6 m/s. It has the same velocity irrespective of its distance from the proton. This is exactly what we might expect if its velocity is dictated by the balance between opposing graviton waves. In contrast, the velocity of electrons in the solar wind may be as low as 10^5 m/s, yet we must assume both are being driven by graviton waves. I believe the differences can be explained by their orientation in flight.
The electron creates a negative electric field composed of e-electon strings that are not in balance with an equal number of p-electon strings. When the electron is in orbit about the proton, its free e-electons become bound to p-electons emanating from the proton, which allows it to move smoothly through space. Scientists know the electron in orbit only spins either up or down. This suggests that the electron is moving smoothly through space, not tumbling end over end. This is what we might expect if the free e-electons are being created from just one sphere of the electron. This sphere becomes oriented towards the proton when its e-electons become bound to the p-electons emanating from the proton as shown in the following illustration.
Notice, if the electron is coming towards the viewer it only has the option of spinning up or down just as experiments verify.
The electron’s remaining strings are acted upon by graviton waves traveling in both directions, which results in the normal velocity of the electron in orbit. It prevents the electron from spiraling into the proton.
In contrast to this situation, when the electron is moving in the solar wind, its free e-electons cause the electron to be out of balance. One sphere will be acted upon with graviton waves more than the other sphere, which will cause the electron to tumble through space. This will cause the electrons in the solar wind to have less velocity than electrons in orbit about protons.
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