When a magnet is heated, you can make a picture of it. The amount of magnetic energy you can create depends on the temperature and the number of electrons in the magnet. The amount of magnetic energy a magnet can have is in nanowatts. When you heat the magnet, the atoms in the magnet become smaller, so they can’t hold much more energy. And, because of the reduction in size, there are fewer electrons.
For small magnet, it’s possible to heat the magnet until its energy is more than enough to hold a few atoms. This is called “hot magnetic interaction.” It usually takes about 1,000 times the energy for a magnet to gain more energy than it loses (or, to use a better-known equation, “hot energy” = energy gained / energy absorbed). The amount of energy needed can vary, depending on the temperature and the number of electrons in the magnet.
However, the number of particles can vary quite much as well, depending on the type of magnet used. In a steel magnet the number of protons is high, and the number of electrons is low. For a gold magnet, only a few protons make up the total energy of the magnet. But, if the number of electrons changes, so does the amount of current. With increasing metal content, this can become unstable.
The problem with magnetic energy is that scientists have to figure out how to get the best out of it (for better or worse). It’s not an easy problem and some theories aren’t very satisfactory.
Some experiments have been done with the idea of changing the atoms in a solid, the way that you change the shape of a marble. In the mid-1990s scientists tried to use magnetic fields to make this happen. They used what’s called “magnetic annealing,” which uses a low magnetic field.
The problem with this technique is that the heat in a magnet affects the temperature of the liquid inside it, increasing the melting temperature and decreasing the melting time for the solid. The liquid doesn’t become liquid until the magnets’ heat rises enough.
In 1993, a team of scientists at the University of Colorado-Boulder conducted a magnetic annealing experiment. They tried to cool a solid to a temperature below where the melting temperature of the solid was. The cooling was quite good, but the reaction was much slower than predicted if the heating was to occur at the right temperature. So, they decided to try to heat the magnet to a high enough
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