Researchers found the exotic state of matter "tetraneutron".

"Scientists have announced the experimental discovery of a tetraneutron, a new and exotic state of matter that could also have properties that are useful in existing or emerging technologies." (SciTechDaily/Experimental Discovery of a Tetraneutron – An Exotic State of Matter)

Tetraneutron is a state of matter that has four neutrons in its structure. That state of matter has finally been confirmed in the laboratory. And the confirmation of the existence of tetraneutron can be more fundamental than we ever expected. It can use to move single neutrons in structures. And it can open the road to new quantum materials.

Quantum materials are similar to nanomaterials. But things like neutrons are forming those structures. Neutrons are promising things for that kind of material.  Quantum materials are similar to nanomaterials. But things like neutrons are forming those structures. Neutrons are promising things for that kind of material. They are bipolar particles that make it possible to connect them by benefiting their poles. 

This thing allows us to make the things like neutron fullerene. In neutron, fullerene neutrons form a similar structure that carbon is forming in fullerene. And theoretically, neutrons can form similar nanotube structures with carbon. That thing allows for the creation of quantum-size machines. Which are even more impressive than nanomachines.

Tetraneutron can open the road to new fundamental materials. Neutrons are bipolar particles. That means there is the possibility to connect them from their poles. If the layer is covered by using a neutron layer. That thing makes it extremely hard. Theoretically is possible to create similar structures that carbon makes in diamonds by using the neutrons. The neutron diamonds are only one thing, that the neutrons can make. If the neutrons can connect freely. That thing makes it possible to create new fundamental quantum materials. 

The neutron stars are the hardest objects in the universe. They are formed of pure neutrons. Neutron stars are given inspiration for one of the hardest possible materials in the universe. There is theoretically possible to cover layers by using one or two neutron layers. And that thing would make the "neutron painting" that is the hardest in the world. Nothing can come through that neutron layer. 

The quantum materials are actually like nanomaterials. But in those materials, the atoms are replaced by using subatomic particles like neutrons and quarks. If we are thinking about the neutron fullerene and neutron nanotubes those structures can make it possible to create unbreakable materials. 

The tetraneutrons can be used in the scanning tunneling microscopes as the scanner antenna. The problem with the regular scanning tunneling microscopes is that they see only layers of the object. They cannot see inside the 3D atomic structure. The scanning tunneling microscopes that are sending neutron radiation can see inside the 3D structures. 

The tetraneutron makes it possible to create new quantum materials and new quantum observation tools. One of those systems is the scanning tunneling microscope that uses a tetraneutron as a stylus. That thing makes it possible to make the scanning tunneling microscope. That makes it possible to hover neutron between the layer and the stylus. That system makes it possible to create a quantum billiard stick that moves single neutrons in space. 

The tetraneutron can use to create very accurate neutron radiation. That neutron radiation can make it possible to move single neutrons in space. And that ability makes it possible to create things like neutron diamonds and neutron fullerene along with neutron nanotubes. 

If the scanning tunneling microscope uses neutrons as the scanner element that opens the road to observe the nucleus of the atoms. But tetraneutrons can open the road to even more fascinating systems. And one of those systems is the neutron maser. The neutron maser forms coherent neutron radiation. That system can use to destroy the single atoms from molecules. Or very accurate X- or gamma-ray microscopes. 

Neutrons can connect to chains. And if the electromagnetic radiation will impact those neutrons they can aim it. When electromagnetic radiation stresses neutron it stores that extra energy in its quantum field. When energy stress ends neutron release that extra energy as neutron radiation. This thing makes the neutron bomb so effective. The tetraneutrons can use the same way to send the neutron radiation. That thing makes it possible to create the most accurate X- or gamma-ray systems in the world.

https://scitechdaily.com/experimental-discovery-of-a-tetraneutron-an-exotic-state-of-matter/