The single-electron quantum circuit can stabilizing by using graphene layers

  

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The single-electron quantum circuit can stabilizing by using graphene layers

The single-electron, 1-dimension quantum circuit can be stabilizing by putting electron move between two graphene layers. The graphene layers would protect the electron when it moves between nanoarrays, which the electrons should affect. 

An electron can get energy from the electromagnetic stress what will conduct it through the graphene layer. The same magnetic field can also input the data to the electron. And the nanoarrays or nanoantennas could call those electrons to them by changing their polarity. So the electrons could travel precisely to the antenna, where it is wanted to travel. 

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The Frankenstein of order. And the new era of the quantum processor.

Above this text is the image that portraits the Frankenstein of Order. The system is at the same time in order and chaos. But the fact is that the wave movement of that network can benefit the new type of graphene-based quantum processors. Which are basing the idea that the graphene layers. Those graphene layers are one on the other are making the layers, which allows creating qubits. 

When in a certain point of the graphene layer is inducting the electricity, that thing will pull this point to another layer. The closing point would make the structure, what is closing another structure and electrons are jumping from the one layer to another. The system can be made by conducting the electricity to both layers. 

And then the certain point of the graphene will push by shooting it to electrons or laser rays. The system can be similar to a scanning-tunneling microscope. The particle will shot to the graphene layer. And that makes the point where the electron can travel from one layer to another. 

The impact of an electron with the graphene layer makes that the impact point of the layer will get closer to another layer. And then the electrons will jump between those layers. So that kind of version will be possible to make the new and extremely small quantum processors. 

That system can also use in the new generation scanning tunneling microscopes. 

The same technology can use also in new scanning tunneling microscopes. The graphene layer where can create the tent-looking structures can form the new type of scanning tunneling microscopes that can scan larger areas than traditional systems.

If the graphene layer can push to dents, what are causing bubbles at the other side this can make it possible to jump a larger number of ions under the bigger layer. This makes it possible to make the scanning tunneling microscopes, which can scan huge areas. And if those bubbles can make freely to graphene layer, that thing makes the system able to scan also layers that are not so smooth as using traditional scanning tunneling microscopes. 

When the graphene layer is equipped with iron atoms and nanotechnical antennas that thing would work perfectly. But if the antenna can replace by using bubbles of the graphene layer, that thing will make those systems less sensitive for the damages.