The new observation tools make a revolution in material- and biological research.
The first image of superpositioned and entangled particles helps model ways to control them better.
The ability to control systems requires that the manipulator sees the targeted system. The top image introduces the quantum ying and yang. That is the first image of a superpositioned and entangled photon pair. These kinds of images make it possible to control quantum entanglement better than ever before.
Maybe quite soon the quantum computers can get stable quantum entanglements. The image shows that energy travels in quantum entanglement like wire travels between two rolls that roll wire from the first to the second roll. This is the reason why both particles in quantum entanglement reach the same energy level. And that breaks the entanglement.
That means the quantum entanglement doesn't seem like a pulley at all. It looks like two rolls where yarn will travel from one roll to another. And this is the thing that makes quantum entanglement fill. Filling the quantum entanglement means that superpositioned and entangled particles reach the same energy level, and that breaks the quantum entanglement.
The transmitting side of the quantum entanglement must be higher than the receiver. So for stabilizing the quantum entanglement energy must dumped out from the receiving particle so that its energy level is always lower than the transmitting particle.
Stabilization of the quantum entanglement means that energy will transfer out from the receiving particle. And also photons are particles. The best way to make energy travel out from the receiving particle is to make the quantum or electromagnetic shadow at the point of the receiving particle.
The system can use two extremely thin laser rays. The first laser ray sends energy and information into the transmitting particle. And then some other particle should cause the electromagnetic shadow at the point of the receiving particle. That electromagnetic shadow pulls energy out from it.
The same systems used to make the image of quantum entanglement can revolutionize science and engineering.
"Visualization of the SNOM (scanning near-field optical microscope) microscope tip exposing material to terahertz light. The colors on the material represent the light-scattering data, and the red and blue lines represent the terahertz waves. Credit: U. S. Department of Energy Ames National Lab"(ScitechDaily.com/Terahertz SNOM Microscope: New Tool Helps Improve Key Quantum Computing Circuit). The SNOM terahertz microscope group can operate like a compound eye. And that makes it a powerful tool.
The ultimate combination in new research where scientists want to observe the behavior of complex systems is terahertz-microscopes and AI. The terahertz microscopes see through barriers. And they can observe things like complex quantum systems and living cells in our bodies. The terahertz microscopes that cooperate with AI are tools. That makes it possible to create new types of complex material structures that are harder than any material before. The AI can handle and observe large structures and entireties.
In high-class material research, terahertz microscopes observe reactions in the system, and then the AI controls energy flows in and out from the entirety. The ability to create new types of atomic and molecular structures revolutionizes many things in engineering and research of complicated molecular and sub-molecular systems. The ability to see systems makes it possible to control them with new accuracy.
https://www.livescience.com/physics-mathematics/quantum-physics/quantum-yin-yang-shows-two-photons-being-entangled-in-real-time
https://scitechdaily.com/magnet-magic-how-ai-is-revolutionizing-material-discovery/
https://scitechdaily.com/new-microscope-uncovers-exciting-insights-into-promising-solar-cell-material/
https://scitechdaily.com/terahertz-snom-microscope-new-tool-helps-improve-key-quantum-computing-circuit/
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