There’s a lot to the question of mass. Most of the mass in a magnetic phenomenon is the magnetic moment. That’s the difference between a current flowing through a metal object or a force. What’s the magnetic moment in a magnet? Well, the answer depends on the material. For example, the simplest magnetic system (which is what we use when we talk about magnetic fields in the outside world) is a coil of wire, where the field is an electrical current. We call that a coil.
A coil is just another example of how mass determines how much energy an electromagnetic phenomenon can hold. Think about something like a bar magnet. Imagine you can’t move it. So you’d have to find the mass of the bar magnet to figure out its mass. You’d have to use the fact that its volume is less than its circumference to figure out that magnet’s mass.
A magnetic field is just a force across a length. You put an electric current through the object, and the field pushes against a force. It’s the opposite of the idea you get from the definition of magnetism. A current in the bar magnet produces a force, but the magnetic flux in the bar magnet doesn’t come from the pressure of the electric current. But that doesn’t matter. In fact, the field pushes against an electric force, and the electric force pushes against the electric force.
The magnetic force from an electromagnetic phenomenon is a combination of all these forces. What’s the value of the magnetic force? That depends a lot on the material that causes the field.
But the magnetic force can take a lot of forms. We could have another magnetic field, such as from water or plasma, which is essentially what’s called a turbulent field. In that case, the force is more like that of a magnet because the field is just the magnetic flux (and so can take several forms). A turbulent field is essentially like what you get with a coil.
And in some cases, we have fields which are not magnetic—for example, the pressure field of boiling fluids. In liquid, when the temperature reaches a certain value, the pressure drops. But if we use a magnetic field instead of pressure, that liquid has an electric field around it which doesn’t change. This is referred to as a non-magnetic, or no-magnetic fluid.
As an example, consider liquid nitrogen (the same element that we have in water). If we can get that magnetic field to be magnetic instead of
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