As scientists recently found out, the so-called “non-ANIONs” retain information about their previous whereabouts when moving, which allows physicists to weave them into complex confused structures with new unusual properties.
To understand the behavior of most subatomic particles, you can imagine an old game where the ball is hidden under one of the three identical opaque glasses, and then moved. As in this game, if you change places with three absolutely identical particles any number of times without tracking their movements, it will not be possible to guess where and which particle will be after the completion of the rearrangement cycle.
However, for non-ABLIENT ENIONs – the opposite is true. Each change in the positions of these bizarre particles makes them intertwine with each other more and more, changing their quantum vibrations and forming an increasingly complex structure that remains visible even after moving them.
To create particles, the Physics team developed a new quantum computer called the “H-Series Quantum Computers” in which the ions of barium and itterbia are held powerful magnetic fields.
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By setting up ions with lasers, scientists turned them into cubes and confused them in a certain way. This gave the cubes the very properties that were predicted in non-abber enyons.
For physicists designing quantum computers, this discovery gives a lot of new opportunities. Typically, cubes are subject to noise and can easily get confused, so scientists are often trying to encode information not in the bits themselves, but in how the bats are located relative to each other.
For analogy, you can present a book where each page is empty, but if you look at all pages at the same time, the information is slowly developing. And even if one