Artificial intelligence can develop new materials.
The thing that artificial intelligence does best is to collect data from limited environments. The AI can work without sleep and follow the processes non-stop. If artificial intelligence has the right tools. It can follow how the atoms are connecting in a certain type of chemical environment.
The AI can follow the images that laser and other microscopes send to the computer and adjust the strength and type of radiation or other energy stress. The system can use different wavelengths of radiation like UV or IR radiation. Or it can remove some frequencies of the EM radiation off. Of course, the AI must have the ability to use UV or IR lights and laser microscopes.
Laser microscopes scan the surface like radars. The UV-lasers are the most accurate optical systems today.
So, laser-microscopes are actually like lidars (laser radars). The accuracy of the system depends on the wavelength of the laser radiation.
But if the system uses more high-energetic radiation. That thing would make it possible to make the revolutionary observation tool called X- or gamma-ray laser microscope. The problem is how to make X- and gamma-rays reflect from the surface.
The X-and gamma-ray microscopes can have extremely high accuracy. The accuracy of the microscopes depends on the wavelength that the system uses. If the scanning laser-microscope uses X- or gamma-rays that system can make ultra-accurate observations about layers. But the problem is that making those systems scan is problematic. There is the possibility to use the side-coming radiation which seeds the elevations. The diagonal X-or gamma-ray source would send the radiation to a gamma-or X-ray camera.
That thing will make the system see the rising atom-size roughness. But the scanning tunneling microscope can be more ultimate tool than X-or gamma-ray laser scanner.
Image II: The model of scanning tunneling microscope
The Higgs boson could use for making the ultimate scanning tunneling microscope.
If we would stop the Higgs boson. And put it in the scanning tunneling microscope. That thing could make it possible to observe reactions. What happens between the nucleus of the atom and electron cores. The ability to stop the Higgs boson and hover it in the scanning tunneling microscope would revolutionize science. Theoretically is possible to create that thing by using quantum annealing.
In that process, the system would stress electrons by using the EM radiation, and maybe that kind of system can raise the energy level of electrons to the level, that they can release the Higgs boson. If that thing can make someday that would give an ability to take images of the individual electrons and maybe it could see quarks. But creating the stopped Higgs boson is difficult.
The accuracy of the scanning tunneling microscope depends on the size of the needle. That needle acts as a small radar. In the most accurate scanning tunneling microscope, the hovering ion or electron is acting like a turntable needle. It hovers between the needle and the surface of the scanned object. That particle follows the form of the layer. The size of that hovering particle determines how accurate that system is. And in the visions is to use stopped Higgs boson that thing allows making observations of the electron cores and quarks.
()https://scitechdaily.com/new-artificial-intelligence-tool-accelerates-discovery-of-truly-new-materials/
Image I:()https://scitechdaily.com/new-artificial-intelligence-tool-accelerates-discovery-of-truly-new-materials/
Image II:()https://www.wikiwand.com/en/Scanning_tunneling_microscope
()https://visionsoftheaiandfuture.blogspot.com/
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