Three-layer graphene and one electron quantum circuit are the ultimate combinations.

The image above: The model of the one-electron quantum system is looking like a pinball.

Three-layer graphene and one electron quantum circuit are the ultimate combinations.

The vision of the compact-size quantum computer requires high-temperature superconducting materials. And a new way to think about computing and microprocessors. The problem is that the superconducting material must keep its form and superconducting ability in the high-temperatures if we want to make the PC-size quantum computer. In superconducting-PC-size computers, the problem is that the needed cooling system has a big size. And that makes the system very large.

The three-layer graphene and the one-electron quantum circuit are the ultimate tools. The three-layer-graphene is making it possible to create superconducting in high temperature can revolutionize computing. The three-layer graphenes can put one on the one to six-layer graphene or nine-layer graphene, which gives the superconductivity the new forms, and that thing would open the new visions for the small-size quantum computers.

The quantum pinball would be the key element of the next-generation quantum processors.

In the one-electron electric circuit, the electrons are traveling between layers of graphene or some other material. That kind of structure can make it possible to make the quantum microchip that can operate at room temperature. The system requires that the electric fields or the effect of outside electric fields are removed from the one-electron quantum circuit. But if that thing is possible, it can open a new road to quantum computers.

The idea of the one-electron quantum circuit is similar to the pinball. The electron hits the gate, and then it would push it, and then the gate would dropdown. The idea of the single-electron circuit would seem very simple, and sometimes people ask, what's the matter with that kind of thing? The one-layer electric circuits are allowing make the multi-level small -size qubit-systems.

The electrons are traveling between the layers, where they are hovering between the graphene or some other material. The electric fields are hovering between those layers. And the idea is that the gate is calling the electron to it. The system registers the change of the electricity in the gate.

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