Sunday, July 5, 2026

The new boost for quantum technology. It will also affect binary computers.



“Proof of quantum effects in a strange metal. Credit: Harald Ritsch / TU Wien. TU Wien has detected strong quantum entanglement for the first time in a centimeter-sized crystal of a strange metal.” (ScitechDaily, Scientists Discover Quantum Entanglement in a Crystal You Can Hold)

“Many quantum effects are easiest to detect in very small systems, such as individual atoms, molecules or photons, that are carefully isolated from their surroundings. But physicists have long wondered whether much larger objects, made of enormous numbers of particles, can also reveal unmistakable signs of quantum behavior.” (ScitechDaily, Scientists Discover Quantum Entanglement in a Crystal You Can Hold)

New observations about quantum entanglement in a centimeter-class special crystal. It is. New boost for quantum technology. The main problem with quantum crystals. That is, which is a better position for quantum entanglement. Should the system make the superposition between atoms? Or should it rather make superpositions between crossing points of those atoms’ quantum fields? 3D quantum crystals. They can form new types of quantum computers.  

It also gives a new boost for classic, binary computers. The ability to create quantum entanglement in a centimeter-sized metal crystal. That is one of the things. That could boost quantum computers. Quantum computers are effective. But they are more effective than binary computers only in certain types of operations. Quantum computers handle data as qubits. 

The qubit has multiple states. The system. It can share data among states. Of the qubits. So, data travels in quantum computers in lines. Or data  travels in a quantum computer in a wider lane than in binary computers. But another thing. It is even more interesting. Each state of a quantum computer. It can act as an independent binary computer. So, if we have a qubit that has 1000 states.

Theoretically. That qubit can replace 1000 binary computers. This is theoretically possible. It's a non-practical way to use quantum computers. The system. It must drive data through the main qubit. And that makes the ability. To use the different quantum states of the qubits as different binary computers. Each state of the qubit. It is in one main state. And that means all data that is driven into the qubit. Must be driven through the main state. 

If. We want to make a system. That mimics human brains. We should create more gates through the qubit's main state. The gate is the tunnel. That transports information. Straight to each state. But that is very difficult. Theoretically, that is possible if we have the internal 2D quantum fields. If those fields. They are on a 2D lattice, and each of those quantum fields. They are in superposition with a similar field structure. The big problem. It is how that information? Can travel through the 2D quantum lattice?. Theoretically. Is possible. To benefit. The quantum tunneling. 

But that means that we need more accurate systems. To drive information separately to each qubit state. Today, quantum computers drive information to the entire qubit. Things like Rydberg atoms make it possible to create. Atom-size qubits. Or quantum processors. 



“YRu3B2 and LuRu3B2 gain their superconductivity from electrons forming flat bands in a kagome lattice, named after a hexagonal Japanese basket-weaving pattern. Credit: Esa Kapila” (ScitechDaily, The Search for Room Temperature Superconductors Just Got a Huge AI Boost). 

The new superconductors can also help keep temperatures low in regular computers. The superconductors and nanonet. It can also trap electrons in its structure. And then those electrons. They can form quantum entanglement. The AI can help to keep conditions stable. The AI can give control systems more accuracy. 

Another thing that can boost quantum computing. Along with AI. They are new superconductors. Superconducting systems. They can also make it possible. To create more effective binary computers. The biggest problem in binary computers. It is the heat. Heat. That forms because of resistance. Resistance causes heat in the wires. The reason for that is the standing waves between atoms in the wire. A superconductor means a situation. That something removes those standing waves. The problem with regular wire is that. The standing waves that form. 

Because of the reflection in the atom’s quantum field. It gets stronger all the time. This causes a chain reaction. There, the electricity. Requires more and more force. To travel through that standing wave. This temperature causes oscillation. And that oscillation disturbs data transportation. The room-temperature superconductors and photonic computers. They can be a solution for the heat problem. The room-temperature superconductor doesn’t mean a superconductor. That works. At 20 Celsius. Temperature. That means. A superconductor. It maintains its superconductivity at temperatures higher than -100 Celsius. One of the solutions. That can make those superconductors more effective. It is high-pressure systems. Those systems decrease resonance. And nanotechnological Faraday cages that protect wires. Another answer. It could be altermagnets. 



“Atomic Structure Altermagnets. An illustration of the atomic structure of altermagnets. Neighboring atoms are rotated. And their magnetic spins are flipped. Credit: Libor Šmejkal & Anna Birk Hellenes.” (ScitechDaily, This Strange New Magnet Could Transform Future Electronics)

“Researchers have designed a diamond-based quantum sensor that could help detect altermagnets, a newly discovered type of magnetic material with unusual properties.” (ScitechDaily, This Strange New Magnet Could Transform Future Electronics)

“For almost 100 years, scientists recognized only two fundamental types of magnets. Now, a much newer class called altermagnets is emerging as one of the most exciting discoveries in physics, with the potential to make future electronics faster and far more energy-efficient.”(ScitechDaily, This Strange New Magnet Could Transform Future Electronics)

“Researchers at the University at Buffalo have now proposed a new quantum sensing technique that could make these elusive materials much easier to identify. Their theoretical approach uses tiny defects inside diamonds to detect the distinctive magnetic behavior that sets altermagnets apart.”(ScitechDaily, This Strange New Magnet Could Transform Future Electronics)

They can remove outside electromagnetic fields. And oscillations at the wire. The oscillation is the thing. That disturbs data transmission. The thing is called altermagnetism. It can revolutionize computing. Altermagnetism is a magnetic effect. That is visible in the metal wires. But there is no magnetism on the shell of that object. Altermagnetism denies the formation of an electromagnetic field around the wire. Those fields are things that cause oscillation. 

When we talk about quantum technology. We must understand that quantum computers are only a small part of quantum technology. Superconductors and many other things could revolutionize electric transportation. The main problem with those things is simple. Keeping electric wires at a low enough temperature. Requires so much power that those systems turn impractical. Quantum systems are tools that come from practical use. They can be used for secure data transmission. Those systems. They can focus very high energy levels in a small point.  

The quantum crystal. It can form a quantum superposition network. That focuses energy into one position. This kind of system can look like an expanding triangle form. At the bottom of that structure will be transmitted radiation. The structure transports energy. 

Focuses it into one point. Quantum system. A stylus. It can adjust electrons’ energy levels. That can make it possible. To create Rydberg atoms. Those atoms can someday be the most effective way. To make the most effective quantum computing systems. The silicon qubits. 2-dimensional lattices. Their information travels between quantum dots. Those dots are electrons that are on those silicon layers. The problem is how to control that system. The system. It requires a very low temperature  to operate. 


https://scitechdaily.com/scientists-discover-quantum-entanglement-in-a-crystal-you-can-hold/


https://scitechdaily.com/the-search-for-room-temperature-superconductors-just-got-a-huge-ai-boost/


https://scitechdaily.com/this-strange-new-magnet-could-transform-future-electronics/

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The new boost for quantum technology. It will also affect binary computers.

“Proof of quantum effects in a strange metal. Credit: Harald Ritsch / TU Wien. TU Wien has detected strong quantum entanglement for the firs...