"An artist’s impression of an analog quantum computer in which atoms are manipulated by lasers to simulate quantum many-body systems. Credit: Image courtesy of Nikita Zemlevskiy, Henry Froland, and Stephan Caspar" (ScitechDaily, Quantum Computers Take a Leap Toward Accurate Nuclear Simulations)
The new quantum computers take a leap into accurate atomic simulations. That improves material research. New materials like ultra-thin superconductors will turn quantum computers into new more compact forms.
That means that. Maybe in the future.
Quantum computers and their coolers can fit in normal rooms. And that is the big advancement.
And many other things. Like fusion reactors and engine technology.
New quantum computers are the ultimate tools in very complex calculations.
There is a point in the formula's complexity. Where the quantum computer becomes more effective than binary computers.
The ultimate complex flow simulations between atoms, ions, and electromagnetic force's interaction with natural forces require ultimate complex calculations. Atoms are complex entireties where four nuclear forces interact with electrons, hadrons, and quarks, that form hadrons. Those simulations leap the quantum computer advancements.
The quantum computers will turn so trustable. That they can be used to develop themselves.
The AI and quantum computers are the ultimate combination.
That makes those systems development faster and more effective than before.
The most effective calculators in the world are tools that can be used to calculate the qubit's behavior in the quantum system. If that behavior can be controlled or predicted that makes quantum computers trusted. The problem is this: if the quantum entanglements in the system are broken without warning that means the data is lost. Quantum computers are good tools for running AI and especially for calculating large entireties.
The thing that breaks even the simplest systems is the entropy. We can think that quantum computers transmit data in a structure that looks like two yarn balls there the string transports information between them. We can think that those strings are like carpets. We can push them forward if they are straight. But then if there is a wave that stretches the carpet.
In quantum systems, the energy travels back to the string. That transports data in the qubit. That forms quantum superposition and entanglement.
That makes waves between those particles. The wave. That forms in the string or belt that transports information warps the string. That string is not a homogenous structure. There are multiple substrings. And when one of those strings that are like a flat cable where wires are separated turns into curves that causes entropy. There is entropy even in the simplest systems. And that entropy destroys or messes up information.
The qubit, quantum superposition, and quantum entanglements are harder to control than nobody predicted. In quantum entanglement, data travels from a higher energy level to a lower energy level particle like the belt. The problem is that those particles form the Moiré pattern when they are put into the superposition and entanglement. That position makes the energy wave in the string or belt that transports data in the superposition and entanglement.
The problem with quantum entanglement is this: Information can travel only from the higher energy level to the lower. So, also energy level between the string that carries data must be higher than the receiving particle. The Moiré effect causes that energy to jump back to the string that carries data.
That effect forms a standing wave between that string and the receiving particle. That pushes the string away from the receiver. This means there is impossible to transport information between particles in quantum entanglement with 100% accuracy. That inaccuracy makes it hard to control the quantum entanglement.
https://scitechdaily.com/quantum-computers-take-a-leap-toward-accurate-nuclear-simulations/
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