"Two twisted boron nitride layers (blue and pink) create a crystal lattice at a distance in which electrons (gold) can arrange themselves in a regular pattern. Credit: Natasha Kiper / ETH Zurich"
"Researchers at ETH Zurich have developed a new technique to better understand how electrons interact within materials. By using a moiré material — created by twisting ultra-thin atomic layers — they generated an artificial crystal lattice in a nearby semiconductor, allowing for more precise studies of electron behavior."
"Scientists have devised a method to create artificial crystal lattices with a large lattice constant in semiconductor materials."
"The increased lattice constant reduces the electrons’ motional energy, making their interactions more prominent."
"This technique will help researchers study electron interactions across different materials."
"A better understanding of these interactions could explain how certain insulators transition into superconductors when extra electrons are introduced"
(ScitechDaily, Scientists Just Found a Mind-Bending Way to Control Electrons)
The ability to control electrons is one of the things that can boost electronics. The system can use the crystal lattice to trap and control electrons using light. The laser beam can affect lattice atoms' conductivity, and that helps to control the electrons in the lattice. In a modified tunneling microscope.
The system operates as tweezers. It can put those electrons into their positions. In the new types of memories and quantum systems, data can be stored in electrons. If researchers want to keep data in the form of electrons they must avoid the situation where electron touches the layer.
Theoretically, the same things that can control electrons can control positrons or antiprotons. The same system that can hover electrons in layers can make the same thing with antiprotons. In antimatter, particles have opposite polarity. And if the system uses electromagnetic force to keep them away from the layer the same system that keeps electrons away from the layer can keep antiprotons away.
That makes it possible to control electrons and antimatter particles with very high accuracy. The system requires ion layers that can push the positron away from the lattices. The ability to store positrons in crystals and graphene can boost antimatter technology. The system must hover antimatter particles between the carbon net structures. Antimatter can have many weapons, and engine solutions. The antimatter can act as a super-power turbo-boost in chemical and ion rockets.
It can make it possible to create extremely small ammunition. One gram of antimatter can destroy Earth. This means. A pistol-bullet-sized antimatter capsule can destroy an entire planet. The antimatter can also be used for data storage. Anti-electrons can store data and when the photonic system reads the anti-electron can be destroyed. There is the possibility to use the anti-electron-electron pair in superpositions in quantum computers.
https://scitechdaily.com/scientists-just-discovered-a-hidden-superpower-in-microscopes-thanks-to-ai/
https://scitechdaily.com/scientists-just-found-a-mind-bending-way-to-control-electrons/
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