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A fullerene-onion consisting of two fullerene molecules superimposed
(Image I)
Holograms, fullerene-onions, and the qubits
Above this text is the image of the graphene-onion or fullerene-onion. The term means overlapping fullerene molecules. The fullerene is the ball-shaped form of graphene. Graphene can allow the creation of new and more powerful microprocessors than ever before.
Fullerene-onions can benefit from quantum computers. The internal fullerene balls can equip with iron atoms. Those atoms are acting like small antennas. And if the electromagnetic stress will impact to internal fullerene ball, that thing makes it possible to resend data to the precise point of the outer fullerene ball.
But the problem is how to input data to the internal fullerene ball because the oscillation must not affect the outer fullerene ball. And one answer would be the hologram, which is formed outside the internal qubit. The hologram would increase the energy level of the internal fullerene, and that thing makes them able to transfer data to the outer fullerene ball.
The hologram can use to make the photon-based qubit. In this case, the 2-dimensional data flow would transform to qubit by transmitting data to the hologram, which brightness can be adjusted very sharply. And the change of the brightness can turn to the data transporter. The brightness of the hologram would determine the level of the qubit. And that thing would make the revolution for the photon-based quantum computers.
But when we are thinking about holograms and data transportation we can use those things otherways. The hologram would transfer the energy to the electrons, or other particles. The idea is that when the brightness of the hologram is increasing that thing will transfer energy to the electrons, which are sending it forward.
The new graphene-based extremely small-size microprocessors might get their energy from the silicon layer, which will be used as the thin solar panel. The temperature of those microprocessors, which are basing the graphene structure must keep at the right level.
And the answer would be that the hologram will transmit light or photons to silicon. That thing makes it possible to adjust the energy levels of the graphene layer very effectively and accurately. Graphene is offering to make a new type of quantum computer that can be smaller than any quantum computer ever been before.
The graphene-based hybrid materials can make it possible to create the smallest microchips ever. And scientists say that new graphene-based microchips are thousand times powerful than traditional microchips.
The system could base the small silicon-iron-carbon hybrid material that is put in the middle of the hexagonal structure of graphene. Then the laser light will shoot to that hybrid molecule. The molecule can send the radio waves to the graphene that is around that small antenna. And that thing will start to send the message forward.
The ultimate small traditional microchips can create on the graphene layer. The atoms that are forming the microchips can shoot over the carbon net. Between the metal atoms and graphene layers could be some kind of insulator, but the most important thing is that the electricity cannot leak to wrong points.
The small-size microchips have one problem and that is overheating. Overheating makes increasing of resistance. That thing can break the atom-sized structures But if those atom size microchips are possible, that thing will make mobile telephones and other devices far more powerful than ever before. And also the power of the normal-size computers will increase.
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Holograms and fullerenes as the tool for the qubits.
The hologram can make it possible to make a new type of quantum processor. In the simplest model, the hologram is making the points where the atoms, ions, or electrons are positioned. And that thing makes it possible to stress those things with magnetic fields or laser rays. If the hologram is made over the electron or proton cloud, the particles that are inside the area of the hologram turn more high-energetic than particles outside the hologram.
In this version, the electrons are closed in the fullerene molecule. If the electrons can stress with an electric field that thing will make them transmit data forward. The problem is how to avoid the stress of the fullerene. The system will work that the electricity is transported to electrons that are inside the fullerene.
The electron cloud could be outside the fullerene, and the energy can transfer through the fullerene. The laser will shoot the fullerene molecule, and cause the radiation that turns the electrons around it, which makes them transmit photons when they are decreasing their energy level.
When the electric load of the electrons or ions will decrease, that thing makes them send radiation, which will conduct to fullerene. If the system uses ions, the ion would hover inside fullerene, and the energy stress will aim in the nucleus. That will cause the electron cores of the atom to start to oscillate, and send the radiation to the fullerene ball.
In some visions of tomorrow, the system will use the superpositioned electrons for transmitting data. In that system would be two chambers. In chamber one the electrons would put to superposition, and then the other side of those superpositions would place in another fullerene chamber. And when the electric level of those electrons will change, that thing will transmit data between chambers.
Sources:
https://eandt.theiet.org/content/articles/2021/02/smallest-microchips-yet-folded-from-graphene/
https://www.zdnet.com/article/tiny-graphene-microchips-could-make-your-phones-and-laptops-thousands-of-times-faster-say-scientists/
https://en.wikipedia.org/wiki/Fullerene
https://en.wikipedia.org/wiki/Graphene
Image I: https://grafexsuperc60.com/comparason-c60-vs-grafex-super-c-60-fullerenes/
Image II: https://grafexsuperc60.com/comparason-c60-vs-grafex-super-c-60-fullerenes/
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