Why is this relevant? What does it mean if magnets lose energy? The answer: they lose it for a few reasons: magnetic repulsion, magnetic compression, and magnetic repulsion and compression. The first reason is quite simple. A magnet is always the same size. It’s a perfect match. Any change in the magnet’s geometry — whether it be the magnet’s field strength/momentum or its density and/or number of “spin” poles — can cause the strength and/or momentum of the magnet to change. And this change in the magnet’s direction and distance can affect its attraction to particles and energy. This is because the magnetic force is always the same, which makes it impossible for the force of gravity (the attraction) to exceed the force of the attraction.
So magnets are always the same size. That means they’re always the same size. The problem is this “always-same-size-with-same-mass-and-momentum-strength” magnet magnet. It can’t do the same thing.
The bigger you make your magnet, the bigger the magnets are going to get. And the smaller you make your magnet, the smaller the magnets are going to get. Now, you don’t want any of this to happen. The smaller your magnets are, the more magnetism there is in them. The more magnetism there is, the stronger things can be. The only way to limit magnetism or to make the magnets so small that the energy/mass of an object is balanced out is to make the magnets in a magnetic field that is strong enough to make the whole magnet. This is called “magnetism.”
Now if you make a small enough magnet, it seems like it’s just going to stay in the same place. But there are a couple of things that make “it stay in place.” One is the size of both the magnet and the particle you want to attract. If they are the same size, they can just “go where they want” — but a magnet is always the same size, not “just going where it wants.” Another thing makes a magnet “stay put.” If the magnet is a constant size, and the magnetic field around the magnet is strong enough to hold the particle within it (its position and mass both being constant) for an extended (for a short period of time) duration period, the particle “gets stuck” on the magnet or something that makes it “stick” to the magnet. This is why magnetism
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