"The Advanced Materials cover illustration shows the surface of the halide perovskite structure being modified by a large organic cation. The cation diffuses through the thin film to reconstruct the surface structure. Credit: Advanced Materials" (ScitechDaily.com/Revolutionizing the Future of Energy: Advancement in Halide Perovskite Solar Cell Technology)
Perovskite can use in advanced nanotechnical armor. When something hits the structure. That is in the picture above this, it presses the upper cubes flat. That ties impact energy while ammunition penetrates the core. And because the material is elastic. Ammunition transmits energy slower to that material than to regular steel. That makes this type of nanotechnical armor more effective than regular armor.
Perovskite can use in a new type of quantum technology. It can revolutionize solar panels. But that structure can also make it possible to create a new type of scanning tunneling microscopes or quantum computers. And perovskite can make gamma-ray lasers possible.
Perovskite structure makes a new type of solar panels possible.
Perovskite is a cube standing on its tip, as you can see from the image at the top. And that structure makes the solar panel more effective. The tapered tip conducts energy to the bottom of the structure.
And that structure also collects energy from the top to the structure's tip. The perovskite structure is also interesting in the tools like the scanning tunneling microscope and quantum computer.
Scanning tunneling microscope.
The perovskite can use to hover ions or electrons over the layer. The scanning tunneling microscope uses the hovering particle for measuring details in materials. But the problem is that the observation area of the tunneling microscope is very thin.
The perovskite structure allows making lots of observation pikes for scanning tunneling microscope. And that thing makes it possible to observe larger areas with incredible accuracy.
Perovskite can also use in nanotechnology.
The perovskite structure allows creating the new type of systems for nanotechnology. The system can use similar technology to scanning tunneling microscopes. The system anchors the nano-size particles between the layers. And the perovskite forms the pylons that keep the layers of that nanosystems away.
Then the system positions nanomachine parts in the right position by shooting them with lasers and magnetic fields. To make this process successful. The system must know each particle's position and its location in the system. So that requires ultimate highly accurate observation systems.
Perovskite in quantum computers.
Perovskite can use to position the electrons in the right positions in the quantum computer. The system puts electrons to hover at the tip of the perovskite. Then the laser ray will make the channel between those electrons. In that case, the electromagnetic shadow between those electrons will make the channel between them. Then the system shoots energy impulses to them.
And that should form photon pair between those electrons. Then the system will superposition and entangle those photons. The electrons form an array that sends and receive information to and from that quantum entanglement. The perovskite structure makes it possible to create multiple quantum entanglement lines that are acting at the same time.
And finally, perovskite can make it possible to create gamma-ray lasers without the need for annihilation.
If the electron stick of superpositioned and entangled electrons that are forming the gamma-ray laser's laser element can position straight in the middle of the perovskite crystals. That would be a very powerful system. If energy impulses to those lined electrons can give straight from perovskite.
That makes the system more powerful than if the system must use some ion or electron layer as the energy aimer. The lined perovskite crystals can use to aim energy impulses straight at the laser element. Regularly gamma-ray lasers use electron or ion clouds to make energy pulses.
The idea is that the system will anchor electrons or negative ions to the tip of perovskite. Then in the middle of that system is the line of superpositioned and entangled electrons. Because the energy level on another side of that electron line is higher than the other, the system can aim an energy burst in the wanted direction.
Then the system will aim energy impulses at those ions or electrons that hang around that electron stick. When energy pumping ends the system those ions send the energy impulse to those electrons.
https://scitechdaily.com/revolutionizing-the-future-of-energy-advancement-in-halide-perovskite-solar-cell-technology/
https://astronomyandtechnology.blogspot.com/
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