Radiation tomography is a multi-use tool.

Radiation tomography can use for making new nanotechnical structures. But the similar systems can also use for fluoroscopy of large-size structures.

The new X-ray tomography systems can observe the inner structure of nanomaterials. The miniaturized X-ray systems can make it possible to create even more advanced and powerful tools for nanotechnology. Because the X-ray tomography can uncover the inner structure of the nanotechnology it can help to make nanomachines with complicated internal structures.

The nano-submarines require an internal power source and microchips that can control their movement. That means the system requires things that allow positioning their parts in the right places. And X-ray tomography is one of the most promising tools in the world.

When we are talking about X-ray tomography we are talking about the X-ray system which is a wheel-looking structure where X-ray transmitters and receivers are on the opposite sides. The fact is that a similar system that can use to research the internal structures of houses and ships can install in the quadcopters.

The transmitting and receiving systems are at the quadcopters that are on opposite sides of the object. And those systems can uncover the internal structures of ships, aircraft, and houses. The system can use gamma-rays, X-rays, and radars for making the fluoroscopy even for the large-scale structures. Then fluoroscopy can use for creating the 3D-holographic models of the structure.

This type of system can uncover the material errors in the space rockets that are at the launching site. Or those quadcopter-based tomography systems can use to uncover structural damages in the houses. But they can also use for intelligence work. They can uncover internal structures of the things like main battle tanks.

Those quadcopters can drop from aircraft. Or they can be delivered even from satellites. So they can slip into the shipyard areas. And operate on the battlefields. And maybe if those radiation transmitters are adjustable. They can use also in the field of medical work in both civil and military areas.

Sources:

https://phys.org/news/2022-04-deeply-nanomaterials-3d-imaging-tool.html

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