"Scientists have unlocked the full statistical fingerprint of quantum entanglement, enabling device testing without needing to know how those devices work. Credit: J-D Bancal (IPhT)" (ScitechDaily, Scientists Crack the Hidden Code of Quantum Entanglement)
"Physicists have made a major leap in our understanding of quantum entanglement by fully mapping out the statistics it can produce – essentially decoding the language of the quantum world." (ScitechDaily, Scientists Crack the Hidden Code of Quantum Entanglement)
"This breakthrough reveals how the bizarre but powerful correlations in quantum systems can be used to test, secure, and certify the behavior of quantum devices, all without knowing their inner workings. The ability to self-test even partially entangled systems now opens doors to more robust quantum communication, encryption, and computing methods. It’s a game-changer for both fundamental physics and real-world quantum tech." (ScitechDaily, Scientists Crack the Hidden Code of Quantum Entanglement)
Because particles spin in opposite directions in the quantum entanglement that causes the counter-wave in the quantum string. Another thing that limits quantum computers is this: quantum entanglement is successful only between photons and the photon's spin is one. And the other particle's spin is 1/2. When the particle turns in the opposite direction the quantum string jumps out from its shell. The only known particle that spins is 1 is a photon.
"A moiré pattern formed by two units of parallel lines, one unit rotated 5° clockwise relative to the other" (Wikipedia, Moiré pattern)
When a particle makes a superposition with some other particle it starts to transmit information to that other particle. That process looks like the belt travels between pulleys. If pulleys rotate back and forth. That makes it hard to put and keep that belt close enough to the pulleys. In quantum entanglement, the string that carries information looks like that belt. That belt must also be at a higher energy level. So that it can transfer information to the receiving particle.
The ability to search the event is important. To control that event the system requires that it knows all things. About that event. The most important effect. In the modern computing is the quantum entanglement. The quantum computers require quantum entanglement for their operations. And the problem is that if something sends energy impulses to the middle of the superpositioned particle pairs.
The problem with quantum entanglement is the heat that raises the temperature in the quantum string that transfers data from the sender to the receiver. The problem with quantum entanglement and its control is that it's impossible to transmit data between sender and receiver without any outcoming effects. Another thing is that the effect called: the Moiré effect, or Moiré patterns causes 100% of data not to reach the receiver. Because in the Moiré pattern, the other particle or pattern moves opposite to the other. Causing quantum noise.
The effect is similar to an event where two plate drums rotate oppositely. If one plate drum touches another a little bit skewed that turns another drum and skews it oppositely. That causes the noise. Same way two superpositioned and entangled particles cause quantum noise. That wave movement is like the thing that travels in the opposite direction than the quantum strings.
The Moiré effect means that when particles turn into superposition and make the quantum entanglement between them the quantum string pushes the receiving particle a little bit. That thing makes that particle pair act like Moiré patterns. Because those particles or patterns are turned oppositely to each other. That forms the standing wave between those structures. That standing wave that forms between quantum entanglement, or superpositioned and entangled particle pairs stretches those quantum strings.
The ability to predict quantum entanglement and its behavior is the thing. That the high-power quantum computers require. To turn themselves more effective. Cracking the code of quantum engagement is the key to better understanding quantum systems. When we create quantum systems. We must realize. That there is always entropy. The growing entropy destroys all quantum systems.
https://scitechdaily.com/scientists-crack-the-hidden-code-of-quantum-entanglement/
https://en.wikipedia.org/wiki/Moiré_pattern
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