Ampère's Right-Hand Grip Rule

A positive ion moving through space will develop a magnetic field around it in such a way that if we point our right hand thumb in the direction of the ion's motion, our gripping fingers curve the same way the magnetic field curves around the ion. This is called Ampère's right-hand grip rule in honour of the man who discovered it.

In general, the rule states that an electric current will always generate a magnetic field around it that curves in such a way that when we point our right hand thumb in the direction of the current, our gripping fingers curve in the direction of the magnetic field.

Ampère's right-hand grip rule.

The way this is explained using the two orb Velcro photon is that the hooks covering the positive ion latch onto the hoops covering the negatively charged orbs of photons. This orients the affected photons in such a way that they start spinning with their axis perpendicular to the direction of motion of the ion.

Since zero-point photons are everywhere in great numbers, a lot of photons are affected by the ion.

There is no lack of photons. Magnetism does not require light or the existence of any other high energy photons. However, high energy photons will also be affected should they strike an ion.

Since photons move in all directions at the speed of light, all photons are uniquely affected by their particular encounter with the ion. But the overall tendency will be to spin in harmony with the direction of motion of the ion. The faster the ion moves, the more photons will harmonize their spin with the ion, and the stronger will be the magnetic field around it.

If we imagine the positive ion moving from right to left, then the photons bouncing off the top of the ion will tend to end up with their negative orbs spinning clockwise. Photons bouncing off the bottom of the ion will also tend to end up with their negative orbs spinning clockwise.

Positive ion producing magnetism in photons by setting their negative orbs spinning.

A ring of magnetism develops around the ion as it sets negative orbs of photons spinning perpendicular to its motion.

An interesting feature of electric currents is that a positive ion moving in one direction has the exact same effect as an identically strong negative ion going in the opposite direction, and herein lies the reason that the Velcro model of the photon has two orbs that spin at the exact same rate but in opposite direction to each other.

To illustrate this, let us consider a negative ion moving from left to right. This should produce the exact same effect as the positive ion moving from right to left.

Just like the positive ion, the negative ion will interact with photons bouncing off of it, causing them to spin. However, instead of a surface covered with hooks, the negative ion has a surface covered with hoops. The negative ion latches onto the hooks of the positive orbs of photons.

Since the negative ion is moving from left to right, it sets photons bouncing off its top spinning with their positive orbs turning in a counter-clockwise direction. Photons bouncing off the ion's bottom also start spinning with their positive orbs in a counter-clockwise direction.

Negative ion producing magnetism in photons by setting their positive orbs spinning.

This means that the negative orbs are spinning in the same direction in both cases. The magnetic field developed around the two ions are therefore identical.

The two orb Velcro model of the photon behaves precisely the way it has to in order to model real world magnetism around charges in motion.