The magnetic field of an induced current is the same as the magnetic field of the conductor itself. Therefore, without a permanent magnet, the induced current will not be able to flow through a wire if the wire is placed in a magnetic field.
So what is the magnetic field of an induced current? It’s the same as the magnetic field of the conductor itself. So the induction coil in the Tesla coil has a field of 0. The induced current in the Tesla coil will be the same as the induced current in the wire itself.
So we have now established that the induced current is a field and therefore its magnetic. Now it’s very important to understand that the induced current in a conductor of a wire is actually a source of electricity. This is because the current in a conductor is not a current but a potential difference. Because the induced current is the same as the potential difference in the conductor, the induced current is a source of electricity.
This is actually very common in electrostatics. The electric field is the current, and the electric current is a source of electricity. So the induced current, like the electric current, is actually a source of electricity.
According to Lenz’s Law, it means that induced currents are often a source of electricity. They can produce sparks and arcs. Even a small current in a conductor can produce a much larger and more damaging electric field. A magnet also produces a magnetic field. A magnet is a source of magnetic fields. So magnets are sources of magnetic fields.
So magnets are sources of magnetic fields. The induced current in the conductor, and the electric current in the magnet, produce the same force.
So magnetism is a force. When we look at magnets, we see that there are certain properties that are characteristic of magnets. We call them “magnetic moments.” Magnetic moments are like charges that point in a certain direction. In other words, they have a magnetic dipole. A magnetic dipole is like a pole with two magnetic poles that are oppositely oriented. When a current flows through a magnetic dipole, an induced current is produced.
The reason magnetic fields are of any sort is because they can be made out to be of any kind. Magnetic field is the electrical field inside the conductor. They have a magnetic dipole, which is a permanent magnetic field. These magnetic fields can be very strong. They can come from electricity, magnetism, or the magnetic field of a conductor.
The magnetic field of an induction coil is the sum of the magnetic fields from the individual turns. The magnetic field of a dipole is an induced field that is created by the current flowing through the dipole. When an induction coil is turned on, the current is induced, which makes the dipole magnetic. This dipole can have a large magnetic field.
It’s common for people to think that the magnetic field of an induction coil is an induced field. The magnetic field of an induction coil can be anything that is induced by an external magnetic field. An induction coil is basically a coil inside a conductor that is made of a conductor instead of another conductor. The magnetic field of an induction coil is exactly the same as a conductor, but the magnetic field of an inductor is different.