How to shoot projectiles through the material without breaking it?

"The model developed at the Vienna University of Technology explains why tiny holes – only a few nanometers in size – are formed in some two-dimensional materials when they are bombarded with highly charged ions, but not in others". 

"The effect of nano-hole formation can be exploited to produce novel sieves for certain molecules. Credit: Vienna University of Technology" (ScitechDaily.com/Seemingly Magical – How To Fire Projectiles Through Materials Without Breaking Anything)

Theoretically is possible to shoot a bullet through the wall without causing stable damage. The bullet's speed must be enormous that it has no time to cut chemical bonds. 

Or bullet will cut the chemical bonds, but it must transfer so much energy in those bonds that they can return to their original form. This thing is made in 2d materials by using ions as bullets. But theoretically, this phenomenon can transfer to regular 3D materials. 

The miracle in 2D material structure: high energy ions can travel through it without breaking anything. Researchers used high-energy Xenon ions in that test. Those ions shot to the graphene layer, where they pushed carbon atoms away from their route. 

In that process, Xenon ions pushed graphene or carbon atoms away from their route. And during that process, those ions deliver energy to those atoms. That causes a situation where those carbon atoms are returning to their positions in the graphene net. 

The same result could do by using electricity conducted on graphene. The idea is that the electromagnetic forces will make the atoms return to their position after the ion traveled across it. This kind of technology can use in quantum computers. In that system, data is transmitted to graphene. 

And then, high-energy ions, electrons, or some other particle will shoot through that graphene. Information will transfer from graphene to those particles that are forming the transmitting part of the superpositioned and entangled particle pairs. 

If that effect can repeat in normal 3D materials. That allows creating the quantum sensors that are more accurate than nothing before them. Superpositioned and entangled ions can also use as an antenna. Or they can use to push ionized atoms. That hover above the fullerene layer. Those ions or anions are hovering by using electromagnetic pushing or pulling effect. That thing can revolutionize nanotechnology. 

That can smell electric vortexes even inside the microprocessors. The idea is that superpositioned particles like an electron would transmit through walls. And then the other side of that quantum yoyo operates as a virtual antenna. 

If that system is someday possible, that system can revolutionize measurement technology. This kind of system can also operate as extremely accurate cutters. And they can push atoms that are hovering on the fullerene layer. So they can make even surgical operations over long distances. In some theories, the Foo-fighters are this kind of quantum yoyos that something uses for analyzing the environment.