"Physicists have uncovered hidden magnetic patterns lurking inside a puzzling state of matter called the pseudogap, which appears just before certain materials become superconductors. Credit: Shutterstock. (ScitechDaily, Superconductivity Breakthrough: Hidden Order Found Inside Quantum Chaos)
We know the thing. Superconductivity makes objects levitate. That levitation is known as the Meissner effect. The effect is formed when all atoms in the system are in the same way. In a very low temperature. Those atoms are in the same quantum field. Because atoms are inside one collective quantum field, that thing makes it possible to push that quantum field up. And because that field is forming a collective bubble that moves the entire object up. In a superconducting wire, the atoms are. Under one collective quantum field. Because electricity travels in that field. There doesn’t form standing waves, and that denies the resistance.
In the Meissner effect, the electromagnetic fields travel past the object. And. That puts the object to levitate.
This effect is not possible in the non-superconducting systems. The reason for that is that entropy doesn’t allow the magnetic fields to push objects above the layer. If it is possible to put the atoms in the system into a similar order. As. They are in the superconducting material. It's possible to form the room-temperature Meissner effect. Electromagnetic radiation can form that levitation. So, the system could use. Coherent X-rays to put those atoms in the right order. In some scenarios, the antimatter annihilation can put those atoms into order. The system uses radiation to force those quantum fields into one entirety. And that forms the virtual superconductivity and Meissner effect in that system.
"Diagram of the Meissner effect. Magnetic field lines, represented as arrows, are excluded from a superconductor when it is below its critical temperature." (Wikipedia, Meissner effect)
Tc=Temperature critical. At that point. The object turns into a superconductor. The Meissner effect is possible. Below that temperature. If the temperature is higher, the EM field travels through the object. And it cannot raise it up from the ground. This thing makes. The Meissner effect can also occur in stealth systems. The system. That can have the superconducting ability. Can push radio waves to travel past the object, making it invisible to radars.
Hidden order in quantum entropy makes it possible to break the quantum network. And its security.
The hidden order found in quantum chaos is one of the most important concepts in quantum technology. The point is that chaos in a limited system cannot be unlimited. The limited chaos means entropy. And the entropy is the thing that makes it impossible to create room-temperature superconductors. But another thing is more important. Chaos protects data that travels in the quantum entanglement. In quantum entanglement. Data travels through an entropic system in a thin fiber.
And the thing that protects data is the system, which travels as a wave in the quantum channel, where the string goes. The quantum channel is like a shadow. That is formed between those superpositioned and entangled particles. If something finds the order in the entropy that surrounds the quantum entanglement. The attacker can theoretically steal information from the quantum system.
The idea is that the string that transports information through entropy acts like a guitar spring. Information travels as waves on those strings. And that puts them in resonance with quantum fields around that string. There is a possibility. That. The attacker can thread superpositioned and entangled particle pairs’ transmitting side to that quantum field which surrounds the quantum string. This could allow the attacker to observe data from the quantum channel.
This requires that the system find the static route through the entropic system. And that is one way to break the quantum networks.
https://scitechdaily.com/superconductivity-breakthrough-hidden-order-found-inside-quantum-chaos/
https://en.wikipedia.org/wiki/Meissner_effect
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