The Electric Field

The electric force can be explained entirely in terms of zero-point neutrinos. All that is required is to give the neutrino the ability to carry a footprint of whatever charged particle it has most recently interacted with.

When a neutrino hits a hook covered quantum, its hoops get drawn out. The neutrino gets a small charge which it carries with it back into space. A neutrino that hits a hoop covered quantum will return to space with its hooks drawn out.

The space surrounding a hook covered quantum is in this way filled with neutrinos with their hoops drawn out. The space surrounding a hoop covered quantum is full of neutrinos with hooks drawn out.

When charged neutrinos hit other charged neutrinos we get one of two types of collisions:

1. If the neutrinos carry different charges, we get an abrasive collision. The hooks and hoops latch briefly onto each other. They make a hard turn and vacate the field in between the two charged quanta. We get a low pressure in the aether.
   
2. If the neutrinos carry the same charge, we get a non-abrasive collision. There is no latching onto the other neutrino. There is no hard turn. The neutrinos stay in the field between the two charged quanta. This gives us a high pressure in the aether.
   

Low and high pressure regions are thus created in the aether by charged surfaces.

Abrasive and non-abrasive collisions of neutrinos between charged surfaces

This explains why opposite charges attract while same charge repel.

Static Charge and Neutral Bodies

When a neutral body comes in contact with a charged body, there is attraction. This may seem strange at first glance. However, it is relatively easy to explain in terms of charged quanta.

A neutral body is only neutral in so far as it has no net charge. Everything is made up of electrons and protons, which again are made up of positive and negative quanta.

A charged surface will pull opposite charges towards it. The distribution of charges in the neutral surface becomes distorted. Attracting charges rise to the surface while repelling charges withdraw into the material.

Neutral surfaces distorted and attracted by charged surfaces

With attracting charges closer to the charged surface than repelling charges, the net effect is attraction.

Each individual section of the neutral surface experiences either attraction or repulsion due to the charged surface. However, on average, the neutrinos inside the field will be of opposite charge due to the difference in distance between repelling and attracting sub-sections of the neutral surface. The majority of neutrinos collide abrasively, leave the field and produce low pressure.