Quantum Entanglement = Sympathetic Vibration
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Quantum entanglement is a quantum mechanical phenomenon in which the quantum states of two or more objects have to be described with reference to each other, even though the individual objects may be spatially separated. This leads to correlations between observable physical properties of the systems. For example, it is possible to prepare two particles in a single quantum state such that when one is observed to be spin-up, the other one will always be observed to be spin-down and vice versa, this despite the fact that it is impossible to predict, according to quantum mechanics, which set of measurements will be observed. As a result, measurements performed on one system seem to be instantaneously influencing other systems entangled with it. But quantum entanglement does not enable the transmission of classical information faster than the speed of light). from www.answers.com http://www.answers.com/topic/quantum-entanglement?cat=technology
"In the past few years, scientists have shown that macroscopic objects can be subjected to quantum entanglement. Pondering the limits of quantum entanglement allows us to consider how quantum mechanics can be unified with physics on a larger scale. There might be something unique about our role as conscious observers of the world around us." Does consciousness change the rules of quantum mechanics?
See Sympathy, Sympathetic Vibration, Sympathetic Oscillation, Quantum Coupling, Vibronic coupling
Quantum Entanglement = Sympathetic Vibration
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MARCH 07, 2013
A team of Chinese physicists have clocked the speed of spooky action at a distance - the seemingly instantaneous interaction between entangled quantum particles - at more than four orders of magnitude faster than light. Their equipment and methodology doesn't allow for an exact speed, but four orders of magnitude puts the figure at around 3 trillion meters per second.
Spooky action at a distance was a term coined by Einstein to describe how entangled quantum particles seem to interact with each other instantaneously, over any distance, breaking the speed of light and thus relativity. As of our current understanding of quantum mechanics, though, it is impossible to send data using quantum entanglement, preserving the theory of relativity. A lot of work is being done in this area, though, and some physicists believe that faster-than-light communication might be possible with some clever manipulation of entangled particles.
Now, thanks to these Chinese physicists - the same ones who broke the quantum teleportation distance record last year - we know that spooky action at a distance has a lower bound of four orders of magnitude faster than light, or around 3 trillion meters per second. We say "at least," because the physicists do not rule out that spooky action is actually instantaneous - but their testing equipment and methodology simply doesn't allow them to get any more accurate. Chinese physicists measure speed of Einstein's "spooky action at a distance": At least 10,000 times faster than light
"....in systems having large numbers of particles, a pair of tiny subsystems tend not to be entangled with each other, but a pair of large subsystems tend to be entangled. If you consider two subsystems each having fewer than about one-fifth of the total number of particles in the overall system, the subsystems are almost certainly not entangled with each other. If the two subsystems are larger than one-fifth of the original system, they are almost certainly entangled. The abrupt change in entanglement behavior is characteristic of the geometry of high-dimensional spaces." http://www.gizmag.com/quantum-entanglement-ubiquitous/27836/
Classical synchronization indicates persistent entanglement in isolated quantum systems https://phys.org/news/2017-05-classical-synchronization-persistent-entanglement-isolated.html
Engineers at Northwestern University have successfully demonstrated quantum teleportation over a fiber optic cable concurrently carrying conventional internet traffic.
This pioneering achievement, detailed in the journal Optica on December 20, 2024, signifies a substantial leap toward integrating quantum communication with existing network infrastructures.
Quantum teleportation involves the transfer of quantum information through entangled particles, enabling data exchange without the physical movement of particles. This method promises ultra-fast and secure communication channels. The Northwestern team, led by Professor Prem Kumar, navigated the complexities of transmitting delicate quantum signals alongside robust classical data by selecting less congested light wavelengths and implementing specialized noise-reducing filters. Their experiments over a 30-kilometer fiber optic cable confirmed the harmonious coexistence of quantum and classical data streams.
Professor Kumar expressed the significance of this development, stating, “This is incredibly exciting because nobody thought it was possible. Our work shows a path towards next-generation quantum and classical networks sharing a unified fiber optic infrastructure.”
This achievement holds profound implications for the future of technology:
• Unified Infrastructure: The ability to transmit quantum information over existing internet cables suggests that future quantum networks can be deployed without the necessity for entirely new infrastructure, streamlining the integration process.
• Enhanced Communication: Quantum teleportation offers the potential for near-instantaneous data transfer, revolutionizing fields that require rapid information exchange.
• Advanced Technologies: The successful integration of quantum and classical communications paves the way for innovations in quantum computing and sensing technologies, potentially leading to more secure and efficient systems.
Looking ahead, the research team plans to extend their experiments over longer distances and through real-world optical cables, further exploring the practical applications of quantum connectivity. This work represents a major step toward unified quantum-classical network systems, heralding a new era in communication technology. 
See Also
Action at a distance
Affinity
Connecting Link what connects objects, connecting media.
Dirac equation
Entanglement
Keelys Accomplishments
law of sympathy
Mind to Mind
Non-Locality
Omnipresence
Quantum Coupling
Remote Viewing
Sympathetic Association
Sympathetic Negative Transmitter
Sympathetic Oscillation
Sympathetic Transmission
Sympathetic Transmitter
sympathetic transmitting system
Sympathetic Vibration
Sympathy
Telepathy
The Mathematical Foundations of Quantum Mechanics
Ubiquitous
Vibronic coupling