There are two factors at play here.
First is the power of the magneto. In general, the magneto has a tendency to increase the number of electrons that spin around it (to a certain extent, the faster they spin). So the faster you can spin the magneto, the more electrons you would get that would be able to spin around it. So the faster you can spin the magneto, the more electrons will be able to spin around it. This also means the faster you spin, the faster the charge can go. If you spin the magneto as fast as you can, the fastest electrons will have to spin to get to the opposite pole from where they want to go. This means that there is a limit to the magnetic energy.
The magnetic energy is limited by the amount of energy that the magneto is able to get from the magnetic field (from the flux) and from the spin. Therefore, as the magnetic flux becomes larger the power of the magneto is limited by the number of electrons that can be turned around in order to get a certain amount of magnetic energy. A good example of how this works is when the power of the magneto decreases. If you increase the number of electrons that spin around a magnetic field, the number of electrons that are able to generate the magnetic field has to decrease.
Now what is the difference between an electric and a magnetic field?
Let me explain this one. When a magnetic field is applied to a surface by a transformer or a superconducting coil, it produces a force. This force is referred to as the electric field. The more force you apply, the bigger the force.
The magnetic field created by a transformer or the coil produces zero power. It doesn’t create any magnetic energy. Since it doesn’t convert the magnetic flux into electricity it isn’t a source of direct current. Therefore, the amount of magnetic energy is proportional to the amount of energy applied. So a smaller field produces a smaller amount of magnetic energy, and vice versa. However, as you can imagine, you can imagine fields up to a few million volts. The magnetic energy is the difference between the two fields. It is the difference between the field and the actual flux.
The magnetic flux is, of course, the ratio between the fields. That means you can have different fluxes. To put it very simply, if your flux is greater than the magnetic flux of a material, then it’s a ferromagnet. If
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