Electrons disrupt the weak field produced by an orbiting \(p^{+}\) that attracts a \(g^{+}\) particle. When an electron is captured by the \(p^{+}\), the \(g^{+}\) particle orbiting at light speed breaks away and since gravity is negative downwards, the \(g^{+}\) particle floats upwards.
In an established potential field, particle relocate themselves to locations equal to their potential. Positive \(g^{+}\) particles do not race to the center of Earth because of the negative gravitational potential there.
As \(g^{+}\) particles rise to the surface, they slow and bunch up into a positive potential front. \(g^{-}\) particles that are also liberated are attracted to this front and follows the positive particles upwards. Subsequent collapses in the crystalline strata generate further such fronts and we have a longitudinal wave of alternating gravity charged particle layers racing to the surface of Earth. As this wave pass through the surface, \(g^{+}\) particles heave the ground upwards and \(g^{-}\) particles pulls the ground downwards at an acceleration greater than one \(g\).
It could happen that only the positive \(g^{+}\) particle fronts race to the surface when such positive front fails to attract \(g^{-}\) particles to follow it. In this case, the up heave is of lesser strength and the ground returns at an acceleration of \(g\) when the train of \(g^{+}\) particles passes beyond the surface. The \(g^{-}\) particles speed downward towards the Earth's core. Given its initial orbiting speed at light speed, they will pass the locations of their gravitational potential and be shot back upwards as their kinetic energy reaches zero. If they reach the surface, they maybe experienced as aftershock, that pulls that ground downwards and cause weakened structures to collapse.
Are aftershock only downward pull without an initial up heave?
Do some earthquakes have a greater downward pull than normal gravity, \(g\)?
With an up heave (\(g^{+}\) particles), such earthquakes will be identified as longitudinal, originating from underground; with only a downward pull (\(g^{-}\) particles only) regions off center from the quakes may experience a side-ward shift as earth refills the collapsed region. Without an up heave, such quakes maybe identified as transverse along the radius through Earth's center.
This scenario also suggests that electrons pass through two molecular layers in the crystalline structure in the order of seconds, so much so that gravity particles are released as a low frequency wave just as we experience tremors on Earth's surface in low frequency of a few Hertz as earthquakes last.
It is expected that the gravity wave bunch up as it slows on the way to the surface. The wave increases in frequency as it slows on the way to the surface. Electrons that generates this wave is expected to travel even slower than the frequency of the tremor on Earth's surface would suggest.
Way to much speculations on a bunch of "maybe"s, I know. But we inch forward in understanding the nature of the crystalline structure that cause earthquakes when underground lightning occurs.
Maybe...
