It must therefore be assumed that any collision between two neutrinos renders the neutrinos completely neutral after the collision.
Collisions between equally charged neutrinos result in a bounce in which the neutrinos stay in the field, producing over-pressure, known to us as repulsion. Collisions between oppositely charged neutrinos result in a hard turn in which the neutrinos leave the field, producing under-pressure, known to us as attraction.
After such collisions, the neutrinos are restored to their original neutral form.
Neutral neutrinos do not react with each other. Their hooks and hoops are such arranged that their surface is perfectly smooth.
Any collision between truly neutral neutrinos result in perfectly random bounces that produce no over-pressure or under-pressure.
However, neutrinos that have bounced off a massive object like our planet are all charged. They have either bounced off a positively charged nucleus or a negatively charged electron. These neutrinos are only neutral in that their sum averages out to zero.
When these charged neutrinos collide with neutrinos emanating from another massive object, such as our moon, they have a fifty fifty chance of being bouncy or reactive. The collisions net out to zero. But because hooks on hooks collisions are slightly reactive, there is a tiny attractive force.
Since neutrinos are so small that they easily penetrate large objects, collisions between neutrinos and massive objects do not only happen at the surface. They happen throughout the massive body. Information of net charge neutrality comes from within the entire body.
However, there is a net charge known to exist at the surface of all massive bodies. This net charge is communicated by neutrinos that happen to bounce off the surface. This is communicated as electrostatic repulsion.
Electrostatic repulsion is calculated from the surface of massive bodies, while net charge neutrality is calculated from the center of bodies. At a distance, where there is little difference between surface to surface and center to center distances, the gravitational force wins out. We get net attraction between massive objects.
But at closer range, where the difference between surface to surface and center to center distances are significant, we get repulsion. Two massive bodies in extreme close contact will repel each other.
However, at larger distances, the electrostatic force becomes merely a repelling vector in the overall calculation in which the overall picture is one of net neutrality. This in turn results in gravitational attraction due to the tiny imperfection in the repelling force produced by hooks on hooks collisions.
Electrostatic repulsion is calculated between surfaces,
Gravitational attraction is calculated between centers of mass
Gravitational attraction is calculated between centers of mass
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