"Scientists have demonstrated a breakthrough method. For building true 3D silicon chips. By stacking multiple layers of circuits. Without damaging existing electronics. The advance could help extend Moore’s law and deliver faster, more efficient computing as traditional chip scaling reaches its limits. Credit: Shutterstock." (ScitechDaily, The Next Computing Revolution May Come From Stacking Chips Like Skyscrapers)
The paradox of computing is this. There is never enough power for those systems. The new high-power computing that revolutionizes mathematics. Forces to develop new systems. That can resist attacks from new systems. The ability to create new protective algorithms. That can resist new complicated malware. Requires high-power computing. The problem is that. The microchips that run those AI-based algorithms. Running with full power. And that means. When new applications come.
The entire physical system must be changed. The new types of quantum computers are tools. That can break any code. The role of those systems is simple. They can create new, ultra-long quantum prime numbers. The attacking systems require those prime numbers to crack the codes. And when the quantum computers launch an attack. Or assist the attack by generating quantum prime numbers. The only thing that can resist is another quantum computer.
New AI-driven control systems require new and powerful physical systems. And the thing that can help to solve problems is new quantum computers. The paradox is this. A fully functional quantum computer requires highly effective AI to control it. The operating systems of those quantum computers are very complicated. They require powerful microprocessors. But in mobile systems, the space is limited.
“Researchers have shown that elusive magnetic excitations can survive far longer than previously thought, opening new possibilities for ultra-compact quantum devices. Credit: Shutterstock” (SvitechDaily,Magnon Breakthrough Could Shrink Quantum Computers to the Size of a Penny)
The answer to that problem is technology, known as vertical integration. In those systems, the microcircuits are like towers. And that makes it possible to increase the number of transistors in those new 3D circuits. The system can keep. The temperature is lowered by using the small air channels. Or a nanotube-based architecture. There, the nanotubes are connected to a heat exchanger. That exhanger. It can be the element.
Connected to those nanotubes. And the cold gas or liquid travels through those elements. That pumps the temperature. Out of those microchips. These kinds of microchips can control quantum computers in the future. And those heat exchangers can be connected to the cooler systems of the quantum chips.
The quantum computer. It can be the size of a penny. If those quantum processors turn operational. They can miniaturize. The size of computer centers. The 250-qubit quantum computer matches the 250 regular microchips. That is one of the most effective systems. These kinds of systems can use the superconducting qubits.
Another version is to use magnons. Anyway, those qubits require. A very stable and low temperature. The small quantum computer requires high-power coolers. So, theoretically. It's possible to keep its temperature low. By putting it into the thermos box. There, the system keeps the temperature at a low level. The system can also use pressure. To raise the temperature that the superconductor requires.
Magnon it is. “A magnon is a quasiparticle, a collective excitation of the spin structure of an electron in a crystal lattice. In the equivalent wave picture of quantum mechanics, a magnon can be viewed as a quantized spin wave. Magnons carry a fixed amount of energy and lattice momentum, and are spin-1, indicating they obey boson behavior.” (Wikipedia, Magnon)
“A lifetime of 18 microseconds could turn magnons from weak intermediate links into strong quantum memories and efficient communication channels on a chip. They may be able to connect hundreds of qubits through a shared pathway, serving as a long-awaited quantum bus for scalable quantum computers.” (ScitechDaily, Magnon Breakthrough Could Shrink Quantum Computers to the Size of a Penny)
“The new MultiQ-IT prototype can cool, trap, filter, and redirect over a billion ions simultaneously, dramatically improving dynamic range and signal-to-noise. Credit: Lori Chertoff/The Rockefeller University” (ScitechDaily, Magnon Breakthrough Could Shrink Quantum Computers to the Size of a Penny)
In some very exciting models. The quantum chip can involve a laser network. The points where the laser beams interact can act as quantum dots. And superpositions could be made through or between those quantum dots. Those systems are exciting. But they are a little bit. Too complicated. For the existing modern technology. The ability to miniaturize the quantum computers is exciting.
When the system requires the ability to control qubits. It must see them. This is the reason. For why the new sensor is interesting. The ability to see the points of atoms and molecules makes it possible to control them. The ability to see atoms and particles. And the ability to inject energy into them. Makes it possible to use atoms as qubits.
In the same way. Those sensors. They can observe the qubits. These are created between quantum dots. The mass spectrometers. They can see which. Of those atom groups are stressed. Mass spectrometers can also transform the atoms into information. They can observe atoms. And a certain atom group. It can be a certain qubit or a state of the qubit.
https://scitechdaily.com/magnon-breakthrough-could-shrink-quantum-computers-to-the-size-of-a-penny/
https://scitechdaily.com/mass-spectrometry-breakthrough-detects-billions-of-molecules-at-once/
https://scitechdaily.com/the-next-computing-revolution-may-come-from-stacking-chips-like-skyscrapers/
https://en.wikipedia.org/wiki/Magnon
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