Metamaterials are the next-generation bricks for many purposes.

Metamaterials are the next-generation bricks for many purposes.

Metamaterials are engineered materials that have properties not usually found in nature. Or otherwise, we can say: Metamaterials are substances with abilities that natural materials don't have. 

Metamaterials can use to transport data into quantum computers. Or they can otherwise revolutionize communication. And of course, things like stealth technology and other kinds of things like ultra-light and ultra-strong materials can be made using metamaterials. 

Extreme purity gives material abilities that it doesn't otherwise have. The problem with monoatomic structures is energy impacts destroy their structures very easily. 

When energy impulse hits the monoatomic structure. Between those atoms forms standing waves that push atoms away from each other. The thing that makes monoatomic structures fragile is that all atoms in that structure take part in resonance. And there is nothing there the material can dump energy. 

This is why steel is a harder material than iron. When iron atoms are resonating, carbon takes part in oscillation in it. So iron can dump energy into carbon atoms. And if carbon has a fullerene form there is more space in the steel which makes more space where that material can dump resonance. 

Pure silicon is one of those metamaterials. Theoretically is possible that researchers can create a solid quantum processor by using pure silicone plates. But the problem is the heat expansion. Nothing denies the superposition and quantum entanglement between electromagnetic fields of silicon atoms. 

Also, we can think that things like atom-size quantum computers are making all known materials metamaterials. That kind of system allows control of the layers and their oscillation with very high accuracy. The effectiveness of metamaterials depends on number of the control points in the material.

 

"Researchers have developed a method for generating meta-holograms in both the visible and ultraviolet spectral regions, overcoming prior limitations. They also devised a way to encode two distinct holographic phase profiles onto a single metasurface, leveraging polarization characteristics and liquid crystal, leading to potential applications in security technologies. Credit: Nanoscale Horizons". (ScitechDaily.com/Breaking Barriers in Holography: Revolutionary Metamaterials Expand Spectrum Possibilities)

If there are so many control points that the material looks like liquid that makes it possible to create powerful and flexible machines. There is a theoretical possibility the T-1000 liquid metal amoeba that can take any form that it wants. Could be created by using cleaned mercury. If all atoms or their electromagnetic fields in the structure are acting as quantum computers. That makes it possible to create systems that are beyond our wildest dreams. 

There is the possibility that certain types of quantum-size cuts on the material. That makes it possible to create quantum grids that can break up the reflection. In this model, the material pulls certain wavelengths in it. And that thing can use stealth technology or receiver systems.  Or otherwise, metamaterials can adjust the reflection that makes standing lightwave over the material. That protects the material against the effect of impacting radiation. 

100% reflection causes a situation that the material turns invisible. The reason for that is a standing wave. That denies the radiation reaching the object's surface.  

The most well-known metamaterial is graphene. One-atomic layer form of graphite. Graphene is multi-use 2D material. 2D materials can use as platforms in new types of systems. There is the possibility that the silicone atoms are put on the corners of graphene, and that makes it possible to create quantum entanglements and superpositions between those atoms. The graphene will not resonate. And that thing makes it possible to avoid the resonance that impacts graphene from silicon atoms. 

The "cousin of graphene", fullerene that can be a ball-looking carbon molecule can make other materials harder than otherwise. The carbon ball can use in quantum computers to transfer information in multiple quantum state receivers. 

The carbon tube or fullerene carbon nanotubes can use in the new types of laser and maser systems. The system can use atoms that are trapped in nanotubes or sharper saying between those carbon atoms for making the maser effect that can push objects on the layers. 

https://scitechdaily.com/breaking-barriers-in-holography-revolutionary-metamaterials-expand-spectrum-possibilities/?expand_article=1