The electric force

To understand the electric force, gravity and magnetism, we must return to our definition of the aether, because it is the aether that makes action at a distance possible.

We have to keep in mind that the aether is so dense that every particle in it is in physical contact with every neighbouring particle. This means that if we can manipulate the aether between two surfaces in such a way that some of its particles leave this field, we get tremendous tension, forcing the surfaces together. Conversely, if we can manipulate the aether in such a way that particles get sucked into this field, there will be tremendous pressure, forcing the surfaces apart. Unless we re-establish equilibrium, there will be tension or pressure, depending on the situation.

Let us further consider what we have said about textures of particles, and the fact that neutrinos are of mixed texture. Neutrinos receive footprints of whatever surface they were last in contact with. This is information that neutrinos take with them as they return back into the field.

Now, consider what happens when a neutrino with a woolly footprint comes in contact with a neutrino with an abrasive footprint. There is a degree of affinity between the two neutrinos. They latch on to each other. On the other hand, if two neutrinos of identical texture collide, there is virtually no affinity. This means that collisions between equally charged neutrinos are different from collisions of differently charged neutrinos. In fact, we can make the following claim based on observation:

Neutrinos of opposite charge collide in such a way that they have a tendency to leave the field, while neutrinos of identical charge collide in such a way that they have a tendency to stay in the field.

Collision of differently charged neutrinos compared to collision of equally charged neutrinos

With this model, we have an explanation for why surfaces of opposite charge attract each other, while surfaces of same charge repel each other. It all boils down to the neutrinos in the aether and how they tend to leave the field when differently charged, and stay in the field if equally charged.

A consequence of this is that there must be electric pressure inside electrons and protons. The walls inside electrons are predominantly negatively charged, and the walls inside protons are predominantly positively charged. In both cases we have a situation in which neutrinos will tend to stay inside. This makes electrons and protons more like inflated balls than saggy balloons. It makes them bouncy, as required for the bouncing electron hypothesis to work.

On a final note, the relationship between the aether and what we call space should not be forgotten. Space is a void filled with aether. When we manipulate the aether, we are in fact manipulating space itself.