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This is interesting. As I was watching it, the question arises as to what is this good for? How can this phenomenon be put to good use?
There may be some applications for this, such as nuclear fusion. But how? Nuclear fusion usually means very hot temperatures, does it not? This quantum effect only works near absolute zero, which is as cold as it gets. But certain types of fusion techniques do not require high temperatures. In fact, if high temperatures occur, the technique cannot work. This would be Polywell fusion.
Polywell fusion attempts to overcome the Coulomb Barrier by concentrating a lot of electrons in a cloud, which creates a deep "well" of negative charge. The deep well is said to facilitate fusion through kinetic energy. There is another form of fusion which brings together a heavier negative charged mass called a "muon", which brings the hydrogen nucleus close enough together to create fusion.
The idea I had is to bring together the electrons in a well of very cold temperatures. It would be a frozen polywell, you might say. One of the problems of Polywell fusion is the difficulty in controlling the electrons. What if very cold temperatures controls the electrons really well? According to the video below, quantum locking actually does this very thing. Maybe the electrons act like a Bose-Einstein condensate, and clump together. In the video below, they pair together. Pairs or clumps could make for the mass increase that the muons do and then some. Maybe this could work in a fusion device.
The video starts below:
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