Quantum teleportation and wave-particle duality are powerful tools in quantum computing.

"In the three layers of graphene depicted here, local twist angle can range from around 1.5 degrees (blue)—close to the "magic angle" for this device—to around 1.9 degrees (red). The arrow shows a twist angle vortex or Twiston. These areas of disorder help make the overall device more orderly. Credit: Simon Turkel"(Phys.org/In a sea of magic angles, 'Twistons' keep electrons flowing through three layers of graphene)

Electrons that are hovering above the graphene layer and the synthetic particles can make a new type of quantum teleportation possible. 

Magic angle "Twistons" are making electrons hover above three-layer graphene. If the electrons are on both sides of the graphene. That thing makes it possible to make superposition and quantum entanglement through the graphene layer. The information can send to those electrons by using electromagnetic radiation. 

And that thing can make it possible to make the new and powerful quantum computers. If there is a quantum field between those electrons. That makes it possible to transfer information between those electrons. 

If those electrons are superpositioned and entangled. Changes in the energy level cause changes in the rotation speed or spin of those electrons. And that makes them send the photon. That means the photons are making it possible to transfer information from the quantum system to the binary system. That happens by sending those photons to the photovoltaic cell. 

But when we are thinking possibility to make a new type of lightweight. And solid-state quantum computers silicone has been shown one of the most promising materials in that kind of thing. The superposition between the silicon atoms can also make through the graphene layer. So there are two silicone layers and graphene will be between them. 

There is possible to make two opposite rotating electromagnetic fields in the graphene layer. That thing makes it possible to make the wave-particle duality or synthetic sterile particles in the graphene. And those sterile particles are making flexible quantum computers possible. The problem with natural particles is that they must be clean. Before they are used as a qubit. If the quantum computer can use the sterile particles that make it faster and more flexible. 

When a qubit is traveling in the system it must be protected against outcoming influence. In some visions, long-distance quantum communication will happen by putting qubit travel between the waves of the wave movement. 

New findings in the matter-wave duality make it possible to create synthetic particles in the laboratory. Even if the system can create only photons. That thing makes it possible to turn wave movement to the sterile photons. 

But if things like sterile neutrino are possible to create in the laboratory. Those sterile particles make it possible to create long-distance quantum communication. In those systems, the sterile particle will shoot to the receiver by using the laser or some other coherent electromagnetic radiation. 

https://phys.org/news/2022-04-discovery-matter-wave-polaritons-photonic-quantum.html

https://phys.org/news/2022-04-sea-magic-angles-twistons-electrons.html

https://scitechdaily.com/breakthrough-in-electrically-tunable-graphene-devices-could-lead-to-the-development-of-beyond-5g-wireless-technology/

 https://miraclesofthequantumworld.blogspot.com/