Image I
The metallic atoms can hover between two magnets. The old trick can make it possible to levitate small metal particles between two layers. And the same system can use to levitate things like ions or atoms between layers.
The thing that makes this kind of system important in quantum computers the qubits are hovering in the chamber where they are protected against the outcoming radiation and magnetic effects. Those qubits are losing their data if they are touching the walls of the system. And the small outcoming magnetic field can destroy the data.
The qubits are effective data transportation and storage tools. But same time qubits are very sensitive. Even light that impacts qubits causes problems in those highly controlled systems. Especially in quantum annealing-based quantum systems, the accuracy of the radiation stress is the key. The power of the dose of the stress radiation must control extremely accurately or the system has problems separating the different layers or states of the qubit.
In quantum annealing systems, the most important thing is to control the annealing of the qubits. The unexpected radiation stress can cause that the computer loses control of the qubits.
The levitating qubits are the new opportunity for making the new and more powerful quantum computers. The problem with this kind of system is that also gravity is affecting those small systems. And one of the answers for the stabilization of the qubit is the data-handling satellites. In that kind of solution, the zero-gravity conditions are making it easier to control the position of the qubits.
Image II
One vision of quantum computers is the graphene network where inside each of the carbon circles is the metal atom. The image of the graphene is in Image II. In the quantum system, the qubit will position to the middle of those atoms. Radiation is stressing the metallic atoms that are in the carbon cell. Those atoms are rotating and send the radiation to the graphene or 2D carbon atomic cells that are put in the rows.
One version of the quantum wire is the line of the 2D carbon atom cells. In those structures is the qubit inside them. That system is of course, sensitive against outcoming stress. The satellite where the quantum system is closed under a liquid-hydrogen shield can give a solution for the problems of the unexpecting radiation stress. The liquid hydrogen is one of the best radiation shields. And the quantum system that is frozen in the zero-kelvin temperature is protected against outcoming radiation.
The quantum wire can act the same way as the quantum computer, and transport data. The fullerene nanotubes can also be used as quantum wires and quantum processors. Stabilizing those qubits is extremely important. And that means the quantum computer of the future can be the satellite, that is located in Lagrange point. The quantum computer's remote control can make by using laser communication. Laser communication doesn't cause unexpected electromagnetic fields around the qubits.
()https://www.scientiststudy.com/2021/08/levitation-classic-magic-trick-may.html?m=1
()https://scitechdaily.com/researchers-around-the-world-are-buzzing-about-a-candidate-superconductor-created-at-quantum-foundry/
Image I():https://www.scientiststudy.com/2021/08/levitation-classic-magic-trick-may.html?m=1
Image II()https://scitechdaily.com/researchers-around-the-world-are-buzzing-about-a-candidate-superconductor-created-at-quantum-foundry/
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