The tale of unbreakable material.
"Matter behaves strangely at the quantum scale, where forces can bind three or more atoms even when two alone would not stay together. Purdue University researchers have now completed a massive quantum calculation showing how this peculiar “Efimov effect” plays out in five atoms. Credit: SciTechDaily.com" (ScitechDaily, Quantum Oddity: Physicists Crack 15-Year-Old, 5-Atom Puzzle)
"The Efimov effect is an effect in the quantum mechanics of few-body systems predicted by the Russian theoretical physicist V. N. Efimov in 1970. Efimov's effect is where three identical bosons interact, with the prediction of an infinite series of excited three-body energy levels when a two-body state is exactly at the dissociation threshold. One corollary is that there exist bound states (called Efimov states) of three bosons even if the two-particle attraction is too weak to allow two bosons to form a pair. A (three-particle) Efimov state, where the (two-body) sub-systems are unbound, is often depicted symbolically by the Borromean rings. This means that if one of the particles is removed, the remaining two fall apart. In this case, the Efimov state is also called a Borromean state." (Wikipedia, Efimov-effect)
If researchers can change this thing into five atoms, that makes it possible to create more effective and fundamental quantum materials.
If we want to make an unbreakable material, we must only make a system that denies standing waves from the structure. There must be some kind of quantum-thermal pump that can deny standing waves. That destroys the structure. If we think about graphene, there are some kinds of energy strings. That travel through those carbon rings makes the graphene stronger.
Actually, the system requires a saucer. Or a hexagon-shaped structure. The energy ring, like high-energy plasma or skyrmion, surrounds that structure. And that system makes energy travel to the center of the saucer. There must be a laser or some other system that puts energy out from the structure. The energy travels into the middle of the structure, and the electromagnetic thermal pump simply blows that energy out from the structure.
But then, to the new quantum materials.
Quantum computers mimic black holes to analyze cosmic secrets. That means the new era for material research is coming. All matter in the universe interacts with wave movement. And the thing that makes a quantum computer a very effective tool to create new quantum materials is that each quantum state can operate with a single atom or another particle. If we have a quantum computer with 149 states, that means the system can share the material layer into 149 quantum dots, and each quantum layer can operate with its unique area or square. The highly accurate chemistry and physics require powerful calculators. And the ideal situation is that.
The system could follow and adjust all the actors. Those are in the system. At the same time. So what type of new materials can the quantum system create if the system has its own computer for each atom in the system? This kind of system can be the key to new types of materials. But in the most futuristic models, the quantum computer could use superpositioned, and entangled quantum-sized black holes to make stable quantum entanglements in the futuristic quantum computer.
That theoretical system can involve two graphene layers, where those quantum-size black holes are in the opposite-positioned graphene nets or in the fullerene tubes. Then information travels between disks around those black holes. The system drives information to the black hole’s disk. And then the disk at the opposite side of the quantum entanglement. If somebody can create those quantum-sized artificial black holes. That can turn the calculations. And quantum technology forever.
"A close-up of the trapped-ion quantum computer used to simulate quantum-information scrambling circuits. Credit: Quantinuum" (ScitechDaily,Quantum Computers Mimic Black Holes To Probe Cosmic Secrets)
The five-atom problem. Or the so-called Efimov effect can turn material research. That term means the five-atom system. There, the Van Der Waals forces turn so strong. That this structure can stay in form. Those forces are too weak in the two- or three-atom systems. But in the five-atom systems, those forces are strong enough. The reason for that is the fifth atom.
The system can transport energy out of it. From that nose, or lone atom. When there are four more atoms behind that energy flow, the energy will not make so a strong standing wave, or the energy flow from four other atoms breaks that standing wave that forms in energy reflection more easily than if there are only two atoms behind that energy flow.
The energy flow can form a situation where the nose atom pushes those flows away from it. And that doesn’t make a standing wave in the system. The five-atom fullerene ring can be stronger than the six-atom fullerene ring. The energy doesn’t travel between an atom and its pair. If it flows nicely out of the structure.
But then return to the quantum-sized black holes. If those things are possible, they can create material that cannot break. That hypothetical black hole’s role in this material is this. They will move and pull energy out of the material. Those black holes are the most futuristic things. Those black holes offer a place. Where energy from those graphene layers can go in cases where that layer faces the high-energy impulses. Black holes can move that energy out from the layer.
There is one way to make a thing that is almost as effective as those hypothetical quantum-size black holes. That system uses precisely aimed laser- or other EM-beams. Those electromagnetic beams can act as thermal pumps. That moves energy out from the material. And that denies standing waves that destroy the material.
https://scitechdaily.com/quantum-computers-mimic-black-holes-to-probe-cosmic-secrets/
https://scitechdaily.com/quantum-oddity-physicists-crack-15-year-old-5-atom-puzzle/
https://en.wikipedia.org/wiki/Efimov_state
