New materials require new tools.

 New materials require new tools. 

"MIT physicists propose a “neutrino laser,” a quantum-driven burst of neutrinos that could revolutionize communication and medical technology. Credit: Jose-Luis Olivares, MIT; Adapted by SciTechDaily.com" (ScitechDaily, MIT Physicists Propose First-Ever “Neutrino Laser”)

New X-ray systems make it possible for researchers to observe. How electrons change their trajectories when they send photons. When molecules form, those systems can observe how atoms flip their electrons. Those systems really see atoms. They see when the atomic nucleus will turn around. In the atom. And the highly accurate photon beams can control those processes. The ability to see how chemical bonds form, and where electrons really are. Makes it possible to create new materials. 

The highly accurate systems can manipulate single electrons around atoms. And that makes it possible to create things like atom-sized quantum computers. These kinds of systems. Those connected with algorithms and quantum computers make it possible to create new types of small robots. Those robots are smaller than a cell, but high-power quantum computer technology gives them abilities. That can beat large-sized systems. 

The problem with the X-ray impulses is that they can destroy entire molecules. The accuracy of this ksystem, which breaks the entire protein molecule, is incredible. In medical use, that system can break down tumors and blood clots. The problem is how to aim those X-ray impulses at the desired point. The single X-ray radiation burst can terminate complex molecules. This can also make it possible to create systems that break unwanted molecules. Like carbon chains, fullerene, and graphene. Those things are harmful in nature. The system can stress those carbon atoms and make standing waves between atoms. And that can destroy carbon bonds. 

"Direct hit. A soft x-ray (white) hits a holmium atom (green). A photo-electron zooms off the holmium atom, which releases energy (purple) that jumps to the 80-carbon fullerene cage surrounding the holmium. The cage then also loses an electron. Credit: Razib Obaid/University of Connecticut" (ScitechDaily, A Single X-Ray Strike Is Enough to Destroy an Entire Molecule)

Researchers want to create the first neutrino laser. 

MIT physicists want to create the most incredible tool that humans have ever created. The simpler way is to trap neutrinos in the tank. And then shoot them forward using lasers as accelerators. Photons will bomb those neutrinos and make them move forward. That makes it possible to create new types of quantum communication tools. And if neutrinos can be put into superposition and entanglement. That gives new possibilities for quantum computing. 

But there is a possibility of using neutrinos to send electromagnetic radiation. Those kinds of systems are tools that can make new observation tools possible. 

They aim to develop a neutrino laser. The concept in that system is the same as in free-electron lasers. The system pumps energy into the neutrino cloud, and those particles will send energy beams, or photons, to make the beam. Those systems can be used to scan atoms with incredible accuracy. The system’s biggest problem is how to trap neutrinos, which are very weakly interacting particles. That trap can be made using laser beams that create an energy point. That doesn’t let those neutrinos get out. Then another laser or other electromagnetic radiation can send energy stress to those neutrinos. 

Another way to create a neutrino laser could be a system that traps neutrinos in graphene. And the system sends energy stress to those things. The neutrinos at the bottom of the fullerene tube send radiation forward, and the neutrinos. That is around that structure, which pumps radiation to a beam that travels through the nanotube.

The possibility of creating graphene, or other 2D material layers. That can trap neutrinos, making it possible to create a radar that can see atoms from a new perspective. In some ideas, the neutrino can be trapped in a photon. The photon forms the tensor that is used to send energy signals to the neutrino. And the neutrino sends its extra energy to that photon. The system senses changes in photon brightness. 

https://scitechdaily.com/a-single-x-ray-strike-is-enough-to-destroy-an-entire-molecule/

https://scitechdaily.com/illuminating-science-x-rays-visualize-how-one-of-natures-strongest-bonds-breaks/

https://scitechdaily.com/mit-physicists-propose-first-ever-neutrino-laser/

https://scitechdaily.com/its-its-own-new-thing-scientists-discover-new-state-of-quantum-matter/

https://scitechdaily.com/scientists-watch-an-atoms-nucleus-flip-in-real-time-for-the-first-time/