Precisely controlled light makes it possible to create layers that are only three atoms thick.

Making layers that are only three atoms thick can use to make the new extremely small-size microchips. But if those light tweezers can use on a large scale. That means this technology can use to create the new type of quantum materials. To the layers of some other material can put a couple of atom-thick layers.

That is making them harder. But the ability to move single atoms can make it possible to create new and more complicated nanostructures than ever before. If that system is combined with things like fullerene or nanotubes. That means the system can install the iron or some other atoms to the carbon molecules.

And in that case, the Van Der Waals forces between those atoms can use as the glue for making the new and more complicated nanostructures. The ability to move single atoms or only a couple of atoms at the same time makes it possible to create new molecules. Which angles are precisely positioned and that would make a revolution in nanotechnology.

What if we could someday create the fullerene- or graphene-type material that is formed of neutrons?

If we could someday create the laser light that allows moving subatomic particles like neutrons we could make the material. That is harder than any other material.

That material is called "neutron graphene". The "neutron graphene" is one of the most interesting hypothetical materials. If we could make the ball-shaped neutron structure where neutrons are connected with the polar connection that allows us to make the artificial neutron star on earth. If we would put that neutron structure to rotate in the magnetic field. That thing makes it possible to create a new type of generator.

The idea of this material is that the neutrons are making the network like carbon atoms. In that structure, neutrons are connected by using their polarity as the glue. The difference between "neutron graphene" and carbon-based graphene is that the last one is forming of the subatomic particles. The neutron fullerene and neutron graphene are similar materials that is forming neutron stars.

https://scitechdaily.com/controlling-light-more-precisely-than-ever-before-with-a-material-just-three-atoms-thick/

Image:https://scitechdaily.com/images/Controlling-Light-With-a-Material-Three-Atoms-Thick.jpg

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