"By twisting light just right, scientists can now unlock dual hidden images from a single metasurface, ushering in new possibilities for encryption and molecular detection. Credit: Shutterstock" (ScitechDaily, New Tech Uses Twisted Light to Reveal Hidden Images)
The ion traps and twisted light make it possible to create new types of quantum systems. What if researchers can create a particle and trap the twisted light ring around that thing? That could revolutionize quantum technology. If somebody can connect and stabilize twisted light around an ion or electron, that can turn the system into the most accurate scanner that has ever been seen before. The photonic system that can create a “photon smoke ring” and stabilize it around some particle, like an ion or electron, can revolutionize information technology. But that system faces many technical issues.
But theoretically, artificial brains require ions that play the same role as neurotransmitters. And a photonic system that mimics the brain's electrical actions. Miniature particle accelerators act as axons, and they shoot ions through the axon hole. Information is stored in those ions.
The ability to create ions, or electrons that twist light orbits, makes it possible to create a system that operates like a human brain. That ion-photon combination can act in the same role as a neurotransmitter in that system. And if the system can trap that combination at a certain moment, that makes it possible to use the photonic data transmission for the messages that require an extra-fast speed. These kinds of systems mimic human brains. The ability to connect photonics and ions makes it possible to use two quantum lines side-by-side in the system.
One of the most exciting things could be creating the photon ball. Their data transportation photon travels inside this photonic ball. It could be possible to trap the ion-photonic ring inside the fullerene molecule. And that allows the system to transport qubits over a long distance. The long-range qubit will travel in the laser or maser beam. And that thing could make new ways to transport information. The problem is how to make a photonic ring stay around ions?
The problem is that. Stabilizing twisted light is not a very easy thing. The hollow lasers can make photon rings where the waves or curves are one or zero. The other way is to adjust the hollow laser light’s brightness. The hollow lasers can also protect the data that travels inside them. In those cases, the data transportation laser beams travel inside a hollow laser beam that protects them against outsiders.
https://scitechdaily.com/harvard-scientists-unveil-tiny-ring-laser-with-giant-potential/
https://scitechdaily.com/lighting-up-the-ion-trap-fiber-optics-built-into-a-chip-for-quantum-computing/
https://scitechdaily.com/new-tech-uses-twisted-light-to-reveal-hidden-images/
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