That question is the crux of the issue. We don’t understand all the variables; but the theory of light waves as well as the theory of electromagnetism seems to suggest that light can be made by means of a magnetic field. (A field isn’t enough just to keep a current going; you also need some kind of energy to give it this energy.) Therefore, there is some energy to put in, and it doesn’t sound like there is only one way to do this. (We could have used gravity for the reason that gravity only needs a force, not a potential; there are plenty of other possible combinations.) So whether or not free energy is possible, it doesn’t seem particularly likely.
But maybe we have missed the mark, and a free-energy version of the magnetic field doesn’t work (like that used by the sun). In this case, the problem is that the solar system’s magnetic field has strong magnetic fields and strong electromagnetic fields. Since electromagnetic fields interact differently with the universe than the solar magnetic fields do, many scientists suggest that electromagnetic waves, not gravitational waves, are what cause the magnetic fields. So, if I was to create a free-energy version of a magnet, what would be its effect on the universe? Unfortunately, it is not known precisely which forces would cancel each other out.
Nevertheless, it is not obvious what exactly you would have to do — you would have to pick up and place magnetic forces, not gravitational waves. The answer? Just give up. The magnetic field in the solar system doesn’t cause the solar wind, and that is because we live in a universe with no magnetic field (a vacuum). In order for a magnetic field to exist, there would have to be a force, and in order to form one, there would have to be pressure. If your goal is to create a magnetic field on Earth, chances are you can’t do that — but what is possible would be to combine light with electromagnetic waves so that gravitational waves are not necessary.
So where does all this leave the magnetic field at the center of the universe? Well, all the evidence suggests that it was created at the big bang. But the big bang doesn’t seem very big to do that just yet.
Why does a magnetic field not exist in our universe?
If someone were to say to you, “You can imagine a magnetic field that exists but it’s not yet here,” you would probably think that they were making a gross exaggeration.
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