Material that can switch between superconducting and resistant states could make the leap to computer technology.

"Researchers have created a novel hybrid superconductor that integrates magnetic properties, paving the way for more stable quantum computing. Credit: SciTechDaily.com" (ScitechDaily, The Magnetic Twist: Hybrid Superconductors Unlock Quantum Computing Potential)

The problem with superconducting computers is how to close the gate. And the other thing is how to control electricity in that system. If things like voltage are too high electricity jumps between wires. And that thing makes those systems problematic. Also, the system must separate the parts in the data flow. The superconducting computers would be excellent tools. One way to make the logic gate for the system is to create a superconductor that can switch between superconducting and regular states.

The system can use the superconducting material and keep the temperature on the edge of superconductivity. Then the system can use lasers to warm the superconducting material that turns non-superconducting. And then stop the laser stress, which decreases the temperature to the superconducting level.

If some material behaves like a semiconductor in regular microchips. That makes it easier to control the superconducting computers. The system could switch between superconducting and resistant states. The superconducting gate base is an idea that the superconducting microchip uses a much lower electric level than a regular microchip. If the material can jump between superconducting and resistant states fast enough, that makes it possible to use those states as the gates.

Image 2) Neurocomputer.

1) When the material is superconducting, the gate is closed.

2) When the material is in the resistant state. The gate is closed.

The gate has a special purpose in Turing's machine. The binary computer must stop before it takes a new mission. The purpose of those gates is to close disturbing data away from busy microprocessors. The terminal gate's mission is to deny that new data comes into the system at the wrong time. In logic gates, the system cannot control the direction of electricity if it jumps over switches. The logic gate is a combination of transistors and diodes. And if electricity jumps over those components, the gate cannot operate as it should.

In quantum computers, the gate closes the states if they are busy. Quantum computers cannot clog as binary computers. But their states can clog. And that's why the system must know if the state or floor is busy. The quantum computer can make many missions at the same time. And each of its states can act as an independent binary computer. Or binary computer can share the mission between each state.

In virtual quantum computers called neurocomputers, the series of binary computers act like they are the states of the quantum computers. In that system, the primary processor, or the gate computer shares the mission to the binary computer groups. Then the system. That is under one domain collects data back in the order.

The material that can switch its state between superconducting and resistance could revolutionize computing.

The problem is how to make this thing fast enough. If there is superconducting material. That is less than half a degree of temperature between superconducting and non-superconducting states the system can close and open gates simply by changing the temperature or pressure in the wire. When a wire is superconducting. The electricity goes through it. When the superconducting state is turned off, that closes the gate.

Another way to open or close the gate is to use the superconducting material that can switch between superconducting and non-superconducting states using electricity. This kind of material behaves like a semiconductor in regular microchips. When the emitter electricity is on that opens the gate.

And when the electricity is off, that thing closes the gate. The material can have stick or crystal-shaped structures, and if those sticks are in a row and in perfect order. That thing makes the wire superconducting. When those crystals are out of order, that thing denies the superconductivity.

https://www.ibm.com/topics/neural-networks

https://scitechdaily.com/the-magnetic-twist-hybrid-superconductors-unlock-quantum-computing-potential/

https://en.wikipedia.org/wiki/Logic_gate

There is a suggestion that dark matter may have deformed another universe.

The researchers suggest that dark matter is the deformed dark universe. Or in the most exciting theories, dark matter is the dark universe inside our universe. In that theory dark matter is entangled with the visible material. That theory is taken from the multiverse theory. There our visible universe is one of many universes. The other universes can be invisible because their electrons and quarks are different sizes. And that thing makes those other universes invisible to us. Another hypothesis is that the hypothetical other universes send radiation that radiation from our universe pushes away. Things like invisible 9th. planet causes ideas that maybe there is another universe in our universe. The thing that makes the mysterious dark matter interesting is that. The dark matter can form structures that can be similar to visible material. But those structures are not visible. The multiverse theory is not new. The thing in that theory is that there are multiple universes at this moment

The neuroscientists get a new tool, the 1400 terabyte model of human brains.

"Six layers of excitatory neurons color-coded by depth. Credit: Google Research and Lichtman Lab" (SciteechDaily, Harvard and Google Neuroscience Breakthrough: Intricately Detailed 1,400 Terabyte 3D Brain Map) Harvard and Google created the first comprehensive model of human brains. The new computer model consists of 1400 terabytes of data. That thing would be the model. That consists comprehensive dataset about axons and their connections. And that model is the path to the new models or the human brain's digital twins. The digital twin of human brains can mean the AI-based digital model. That consists of data about the blood vessels and neural connections. However, the more advanced models can simulate electric and chemical interactions in the human brain. This project was impossible without AI. That can collect the dataset for that model. The human brain is one of the most complicated structures and interactions between neurotransmitters, axons, and the electrochemica

Nano-acoustic systems make new types of acoustic observation systems possible.

' Acoustic diamonds are a new tool in acoustics. Another way to make very accurate soundwaves is to take a frame of 2D materials like graphene square there is a hole. And then electrons or laser beams can make that structure resonate. Another way is to use the electromagnetic field that resonates with the frame and turns electromagnetic energy into an oscillation in the frame. Nano-acoustic systems can be the next tool for researching the human body. The new sound-wave-based systems make it possible to see individual cells. Those soundwave-based systems or nano-sonars are tools that can have bigger accuracy. Than ever before. The nano-sonar can use nanodiamonds or nanotubes as so-called nano-LRAD systems that send coherent sound waves to the target. In nanotube-based systems, the nanotube can be in the nanodiamond. The term acoustic diamond means a diamond whose system oscillates. The system can create oscillation sending acoustic or electromagnetic waves to the diamond. Diamond

Visions of bright future

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