The tri-layer graphene can turn the new page for superconductivity.

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The tri-layer graphene can turn the new page for superconductivity. 

Twisted tri-layer graphene is probably the key element in tomorrow's supercomputing. Those graphene bites can put one after one in the EMP-protecting tube that protects the data from the outcoming magnetic effects. But the same phenomenon is possible to turn in a tri-layer nanotube, where the carbon atoms are on three layers superimposed. In that structure is three nanotubes one inside the other. 

That thing would make the new type of small-size superconductors possible. Of course, the three-layer square-looking graphene can itself use in superconductors, as I wrote before. 

In that case, the graphene bites will put one after one like cake bites. So in that case the superconductor would be the hexagon-looking structures, which are one after one. The layers of the graphene would put in the protective tube. The purpose of that tube is to protect the superconductor from the effect of outcoming radiation. 

The tri-layer graphene can also connect to a single-electron quantum circuit. That thing can also make a big advantage for the next-generation quantum computers. The electrons can travel between the tri-layer graphene layers and that thing will make it possible to use this kind of system for creating qubits, which can operate at very high temperatures. In the quantum computer. The graphene layers themselves or the electrons between the graphene layers can transmit data. 

Superconductivity is an important thing in supercomputing because the system would be faster and the data transmitting is sharper if the wires are superconducting. The problem with the powerful supercomputers is that they are creating heat, which causes oscillation in the electric wires. And that thing would increase resistance. The oscillation of the wires will cause that the data signal would turn turbulent. And that is making the signal unable to read. So keeping the temperature of the processor low is the key element in fast computers. 

The virtual superconductivity can make the new type of radio amplifiers and transistors possible. 

Unless the real superconductivity, the "virtual superconducting" bases the idea that the energy will just pump from outside to the cable or layer. That thing would use the outcoming energy for keeping the signal strong and easy to separate. That kind of structure can use in the new radio telescopes and radio antennas, which can turn those systems very small and powerful. 

When we are thinking about superconductivity from the point of view of data transmission. There is a possibility to make so-called "virtually superconducting material" using the tri-layer structures. In that kind of structure, the two layers that are both sides of the "virtual superconductors" can input the energy to that layer which helps to keep the signal strong and in form.

https://scitechdaily.com/harvard-scientists-trilayer-graphene-breakthrough-opens-the-door-for-high-temperature-superconductors/

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