The quantum computer will turn from theory to practical solution.

The quantum computer will turn from theory to practical solution.

A long path has been gone from theory to practice in quantum computers. Today's theories are practice in tomorrow. The quantum computer was a theory about ten years ago, and now the computer scientists are telling that they can create a "compact" quantum computer(1), which might be the size of the industrial hall quite soon. The thing that increases the speed and resources for creating a quantum computer is artificial intelligence and new nonlinear programming(2), which allows the computer to find the solutions for the program more independently.

The problem with machine learning is the thing, that the learning machines need extremely powerful computers. And if artificial intelligence can operate by quantum computers, it can have more capacity than ever before. Even the house-size quantum computer can operate remote-control robots by using the internet, and that's why even the large-size quantum computers are interesting tools.

The thing in the qubit is that thing requires an extremely low temperature that the qubit can transport data. Also, things like quantum wires and other things need extremely stable conditions that they would keep their forms because the thing requires that all physical oscillation and electromagnetic fields are removed from the space, where those things are created.

If the quantum wire would oscillate the laser just cannot hit to those atoms, in the angle, where it can make the quantum field around the atoms oscillate to the right direction. The electromagnetic fields would mean that the place of the targeting atom would change, and the laser would not hit the targeted atom.

Sources:

(1) https://phys.org/news/2020-08-path-powerful-quantum.html

(2) https://phys.org/news/2020-08-path-powerful-quantum.html

Image: https://phys.org/news/2020-08-path-powerful-quantum.html

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What if quantum wire would be created by using ions?

@@@@@@@@@@@@@@@@@@@@@@

]]] >> {(+)}{(-)}{(+)}{(-)}{(+)}{(-)}**###

@@@@@@@@@@@@@@@@@@@@@@

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Marks of the diagram

@@: Walls of the nanotube where on the fullerenes is the net of iron atoms. Those iron atoms are removing the magnetic field from the tube that is acting as the Faraday cage.

]]]] : Electron source

>> : Electron

{ } : Quantum field

{(-)} : Minus ion

{(+)} : Plus ion

### : Photon detector (Light cell)

Faraday cage: https://en.wikipedia.org/wiki/Faraday_cage

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The electron's impact with the positive ion will be sure because of the plus mark ion will pull it to impact course.

The pulling force of positive ion would pull electrons to impact it. The problem is that the electron should travel with so low speed, and the electron level should be so low, that the impact will just transfer the energy to the quantum field but not move ion itself.

The electron source will send the electron to the positive ion. Then the movement of that ion would transfer the energy to the quantum field, and the last atom of the line would send the photon to the photon detector. Ion form could make the quantum wire keep its form in the higher temperature. And the system can put in the nanotube, what is covered by the iron network, which makes it the miniature Faraday cage. That thing would make it possible to transmit data without electromagnetic turbulence.

In this scenario, the positive and negative atoms or in this case ions are forming the quantum wire. The electron would hit to the positive ion, and then that ion would move the signal to quantum fields of the chain of those ions. The positive ion should touch the quantum wire so sensitive, that it would just transfer the energy to the field, but leaves ion and it's electrons stable. The thing is that this kind of system requires that every kind of electromagnetic turbulence is eliminated.

So the problem with the qubit is that the laser ray would not hit to the quantum wire, there is a possibility to use the electron ray. or electron what would hit to positive ion. In the ion form of the quantum wire, the atoms would be in the ion form, and that thing would make it easier to hit point the data transporter to the beginning of the quantum wire because the positive ion would pull the negative electron to it.

Plasmonic waves can make new waves in quantum technology.

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Metamaterials can change their properties in an electric- or electro-optical field.

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