The new magnetic-twist paradigm can make quantum computers more effective.

The new magnetic twist paradigm can make quantum computers more effective. It allows sharing of information between multiple quantum systems. And that makes it possible to exchange information between complex quantum systems. The reason, why making superpositions between atoms is so difficult is that atoms have multiple actors, and there is also very much free space. 

Free space in material forms pockets. Where energy can move. That means a large number of oscillations are traveling in those empty free spaces that are between electron shells and quarks. There is the possibility to make the superposition and entanglement between electromagnetic fields around the atom. But the problem is that electrons that orbit atoms make that electromagnetic field unstable. 

"This artistic depiction shows electron fractionalization — in which strongly interacting charges can “fractionalize” into three parts — in the fractional quantum anomalous Hall phase. Credit: Eric Anderson/University of Washington" (ScitechDaily.com/ A Major Quantum Computing Leap With a Magnetic Twist – “A New Paradigm)

Cut information in pieces. And turning it back to its entirety is the key element in quantum computers. The problem with that is. How to protect information when it travels between quantum systems. If some non-controlled effect disturbs or changes the information that travels between systems. The result that the system gives is wrong. The problem with quantum computers is that the only thing that can detect errors is another quantum computer. So only the possibility to transport information in form there are no changes makes quantum computing possible. 

The problem with quantum computers is error detection. The only thing that can check the results that a quantum computer produces is another quantum computer. That's why sharing identical information between quantum systems is extremely important in quantum systems. Quantum technology is not very old. And that means there is not very much experience about those things. 

The image of two black holes that orbit each other could also introduce classic superpositions. The close range of those black holes makes it possible that skyrmions around those things can turn to superposition. And sooner or later, the oscillation of those skyrmions or transition disks makes the black holes oscillate at the same frequency. 

At the quantum level, the accuracy of those oscillations must be high enough. That they can transport information. If there is space that thing causes an effect that energy falls in those empty spaces. And that makes superposition impossible. 

When the quantum system transports information to another quantum system. It sends oscillation to another quantum system. That oscillation adjusts the receiving system. And then it can form the quantum entanglement. When quantum entanglement forms the dominating participant will take touch with the receiving participant's quantum field. 

Then it starts to rotate that quantum field. So the energy that travels between those particles forms a strap that rotates receiving or lower energy level particles in opposite directions. When the energy level between those participants turns stable that forms a standing wave between those particles. And then that destroys the quantum entanglement. 

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