The thing that makes the AI so powerful is simple. It can follow and control large entireties. And it can copy data to the databases so that the system can multiply conditions. When researchers are making new intelligent nanomaterials, they need to handle many variables like pressure, radiation level, temperature, and time that energy stress lasts.
Even a small change in those things can affect the construction of those molecular-size machines and structures. Nanomaterials are materials, that are planned and created with accuracy that are smaller than even atoms. Researchers can create new nanomaterials by using a series of nanotubes.
Those nanotubes are less than a millimeter long, and they form an elastic structure. If those nanotubes are connected with turning joints. In that nanomaterial, there is ball-shaped fullerene between those nanotubes. And that combination gives the material an elastic form. That combination can create a nanotechnical canvas that has brand-new features.
Things that are moving things in nanotechnology require extremely highly accurate tools. And in that process, the particles that are forming nanomaterials must not touch anything when the system connects those things.
"Graphene is an atomic-scale hexagonal lattice made of carbon atoms". (Wikipedia/Graphene)
"Model of the C60 fullerene (buckminsterfullerene)" (Wikipedia/Fullerene)
"Model of the C20 fullerene" (Wikipedia/Fullerene)
Holograms and hovering fullerenes can use to transport atoms. Or even larger structures.
The system can use small-size holograms to adjust the energy levels of the atoms in the nanostructure. When the hologram inputs energy to the atom energy starts to flow to an atom at a lower energy level. And that energy flow can connect those atoms. The thing is that. The developers can create famous lightsabers from Star Wars movies by using the high-temperature hologram that ionizes the air. And then the magnets will pull those ions to the handle of that system. Another interesting tool is the fullerene molecules.
In nature, there are no limits to the size of those ball-shaped carbon molecules. The fullerene molecule can rise the object airborne. The carbon ball will form around the object. And then the system will transmit energy to the top of the fullerene. Below that thing is a colder point. That thing makes plasma and radiation travel below the fullerene.
One of the most fascinating models of those visions is the system, that creates a fullerene or graphene ball around the object. The system can use the air ball or standing pressure wave that forms the fullerene around it. The fact is that we can say large-scale ball-shaped fullerene structures as graphene. Graphene is a 2D carbon structure that can cover large structures by giving them new features.
Graphene or fullerene balls that form a homogenous carbon atom layer over the structure can be used to cover nanotechnical microchips. And that thing gives them new abilities. The Fullerene (or graphene) can cover even large-scale structures.
This thing forms the lifting effect that keeps the fullerene molecule hovering above the ground. There is a possibility that a ball-shaped craft will cover by using carbon atoms that form a fullerene or graphene layer over that ball. Then that fullerene will conduct ion flow to blow it. And then the system makes the structure flow.
https://scitechdaily.com/merging-artificial-intelligence-and-physics-simulations-to-design-innovative-materials/
https://scitechdaily.com/more-practical-for-holography-an-easy-way-of-altering-compact-semiconductor-lasers/
https://en.wikipedia.org/wiki/Fullerene
https://en.wikipedia.org/wiki/Graphene
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