Inducing Current Into a Copper Wire

Imagine a copper wire connected to an ammeter to measure current.

If placed at rest on top of the north or south pole of a magnet, nothing happens. There is no measurable effect of the magnet on the copper wire if nothing moves.

However, if either the magnet or the wire is moved in such a way that the copper wire cuts into the stream of polarized photons coming out of the magnet, then we will register a current.

This can be explained with the two orb Velcro model of the photon as follows.

When a copper wire lies at rest inside a magnetic field, electrons inside the wire are affected by the field in equal measure at either side. The spinning photons streaming into and out of the magnet push electrons at one side of the wire in one direction and electrons at the other side of the wire in the other direction.

This does not produce a net current in the wire since all that happens is that electrons move down one side of the wire and back up on the other side of the wire, completing a local circuit in the stretch of copper wire inside the field.

Electrons spin and move a bit as their hoops get latched onto by the hooks of positive orbs of spinning photons, but there is no net current in the wire.

If we move the copper wire up and down inside the field, nothing change as far as the electrons inside the copper wire is concerned. The spinning photons still affect the electrons equally on both sides of the wire.

However, if we move the copper wire to the side so that it cuts through the field of polarized photons, photons on the cutting side of the copper wire get more traction than the trailing side. The electrons in the wire start moving according to the spin of the photons on the cutting side, and we get a current.

Induction of current into a wire.

Move the copper wire the other way through the field of polarized photons, and the spinning photons on the other side of the wire get more traction. The current starts moving in the other direction.

Turn the magnet, so the other pole points up. Repeat the experiment, and note that the current flows the opposite ways relative to the motion of the wire. The photons are spinning the other way, causing electrons to move in the opposite direction when they get traction.

Keep the wire in position and wave the magnet about instead, and current is also induced. It does not matter if it is the copper wire or the magnetic field that is moved. As long as the wire cuts through the magnetic flux lines, there will be current induced into it.

The flow of electrons inside the rest of the copper wire can be envisioned as a variant of Newton's cradle, with electrons pushing on each other, moving energy down the wire at a tremendous speed.

However, the electrons never touch each other directly. What is happening is that neutrinos between the electrons transfer energy down the line. As explained in the chapter on the neutrino, there is neutrino pressure between electrons. This transfers energy down the line while keeping the electrons from colliding.

Since neutrinos move about at the speed of light, also inside copper wires, a pressure wave develops in which the kinetic energy of electrons affected by the magnetic field is transmitted to the ammeter in an instance.