Image 1) "Artistic rendition of isolated spins on hexagonal boron nitride under an optical microscope. Credit: Qiushi Gu" (ScitechDaily/Quantum Memory: 2D Material Identified That Can Store Quantum Information at Room Temperature). The Boron nitrate can position to the graphene layer. Then data can be driven to those boron nitrate bites.
And then that data can transmit to winger crystal. At room-temperature electrons are trapped in graphene by pushing them with magnetic fields. And maybe someday that technology allows making small, portable, and powerful quantum systems.
The graphene where electrons are trapped in its network structure can operate at room temperature as Wigner crystals. The idea is that electrons that are trapped in the graphene network can position in their places by using electromagnetic fields that are pressing them in position. That thing can use to make the room-temperature operating pocket-size quantum computer.
The new quantum memory that is based on 2D material can have many uses.
The new 2D material hexagonal boron nitrate can make it possible to make small extremely small mass memories that can operate at room temperature. The thing in quantum information storage is that. This kind of thing can use to transport data between quantum computers. Quantum computers can transfer data from that kind of mass memory to quantum computers from portable mass memory in the form of qubits. But this kind of mass memory can use also in quantum computers as the structure of qubits.
The idea is the system uses the Wigner crystal-type solution where electrons, ions like protons, or photons are trapped in graphene structure. Then the data will transfer to those electrons. And then the radio- or some other electromagnetic wave movement will drive through that structure. That electromagnetic wave movement will act as a carrier wave. And that thing can use to transmit data in some quantum computers.
Image 2) "Structure of a two-dimensional Wigner crystal in a parabolic potential trap with 600 electrons. Triangles and squares mark positions of the topological defects". (Wikipedia/Wigner Crystal).
Oppositely positioned Winger crystals can use as qubits. Electrons that are trapped in those structures can be superpositioned. And they can use to make the quantum entanglement in quantum computers.
The data is cut to the smallest possible parts. And then the superposition is made between the electrons or ions that are trapped in two opposite Wigner crystals.
If we are thinking about the possibility to make the quantum computer by using two opposite positioning Winger crystals. There is a possibility to make a pocket-size quantum computer.
The thing that can make it possible to make the room-temperature-operating quantum computer is the graphene net. The electrons that are trapped in the graphene network can push to their place by using magnetic fields. And then the data can transmit by using lasers.
The idea is that quantum data will be driven to that quantum information storage. And then it will transfer to the Wigner crystal where it can transmit forward. If the electrons or qubits can trap in the graphene storage. That will make it possible to make lightweight. But extremely powerful quantum computers.
The same technology, that used in the quantum-USB. Can use to make the quantum computer. The thing is that the quantum-USB-stick is itself the quantum computer. But that system can also connect to the more powerful quantum computers. The idea is that the data is driven to quantum data storage.
And then it will download to the quantum channel. If there are two Wigner crystals opposite to each other. That thing allows driving at the same time. Between opposite electrons or ions etc.
https://scitechdaily.com/quantum-memory-2d-material-identified-that-can-store-quantum-information-at-room-temperature/
https://en.wikipedia.org/wiki/Wigner_crystal
Image 1)https://scitechdaily.com/quantum-memory-2d-material-identified-that-can-store-quantum-information-at-room-temperature/
Image 2) https://en.wikipedia.org/wiki/Wigner_crystal
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