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Trying to solve Quantum Entanglement Device, Casimir device!


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Apparently this Quantum Entanglement Device or in short QED will either "curse" or "bless" the player.

First Time travel and Quantum Entanglement

Quantum-mechanical phenomena such as quantum teleportation, the EPR paradox, or quantum entanglement might appear to create a mechanism that allows for faster-than-light (FTL) communication or time travel, and in fact some interpretations of quantum mechanics such as the Bohm interpretation presume that some information is being exchanged between particles instantaneously in order to maintain correlations between particles. This effect was referred to as "spooky action at a distance" by Einstein.

Nevertheless, the fact that causality is preserved in quantum mechanics is a rigorous result in modern quantum field theories, and therefore modern theories do not allow for time travel or FTL communication. In any specific instance where FTL has been claimed, more detailed analysis has proven that to get a signal, some form of classical communication must also be used. The no-communication theorem also gives a general proof that quantum entanglement cannot be used to transmit information faster than classical signals. The fact that these quantum phenomena apparently do not allow FTL time travel is often overlooked in popular press coverage of quantum teleportation experiments. How the rules of quantum mechanics work to preserve causality is an active area of research.

Quantum Entanglement is connected to Wormholes and Cassimir device:

Raychaudhuri's theorem and exotic matter:

To see why exotic matter is required, consider an incoming light front traveling along geodesics, which then crosses the wormhole and re-expands on the other side. The expansion goes from negative to positive. As the wormhole neck is of finite size, we would not expect caustics to develop, at least within the vicinity of the neck. According to the optical Raychaudhuri's theorem, this requires a violation of the averaged null energy condition. Quantum effects such as the Casimir effect cannot violate the averaged null energy condition in any neighborhood of space with zero curvature, but calculations in semiclassical gravity suggest that quantum effects may be able to violate this condition in curved spacetime. Although it was hoped recently that quantum effects could not violate an achronal version of the averaged null energy condition, violations have nevertheless been found, thus eliminating a basis on which traversable wormholes could be rendered unphysical.

Cassimir and quantums

In quantum field theory, the Casimir effect and the Casimir–Polder force are physical forces arising from a quantized field. The typical example is of two uncharged metallic plates in a vacuum, placed a few micrometers apart, without any external electromagnetic field. In a classical description, the lack of an external field also means that there is no field between the plates, and no force would be measured between them. When this field is instead studied using quantum electrodynamics, it is seen that the plates do affect the virtual photons which constitute the field, and generate a net force—either an attraction or a repulsion depending on the specific arrangement of the two plates. Although the Casimir effect can be expressed in terms of virtual particles interacting with the objects, it is best described and more easily calculated in terms of the zero-point energy of a quantized field in the intervening space between the objects. This force has been measured, and is a striking example of an effect purely due to second quantization. However, the treatment of boundary conditions in these calculations has led to some controversy. In fact "Casimir's original goal was to compute the van der Waals force between polarizable molecules" of the metallic plates. Thus it can be interpreted without any reference to the zero-point energy (vacuum energy) or virtual particles of quantum fields.

Back to Quantum Entanglement Device and its rewarding/cursing. So it being random.

Is Anything Truly Random?

So to find true randomness, Acin and his colleagues turned to the world of atoms and electrons, and to the laws of quantum mechanics.

"To be more precise, we are taking advantage of the nonlocal correlations of entangled quantum particles," he says.

So that means that the laws of quantum mechanics say some things truly are random, like for example, the clicks a Geiger counter makes when it measures something radioactive.

"Those are random, due to quantum mechanics," says Christopher Monroe, Acin's colleague at the University of Maryland.

But Monroe says there's a problem with the random clicks of a Geiger counter. You can't be certain that the box the counter is in doesn't have a mechanical flaw, or even worse, a device that records the clicks and sends them to your enemy.

"A stronger form of random-number generators are so-called device independent. It doesn't matter what's inside the box," Monroe says.

Tied Up In Quantum Entanglement

This is where the weird properties of quantum mechanics come in. In this world, you can have a magnet that is pointing north and south at the same time, so long as you don't look at it.

"And when you do look, it randomly pops into one or the other," Monroe says.

So to capture that random popping, Monroe took an atom of ytterbium (a soft silvery metallic element), which has "an outer electron that is very much like a bar magnet," he says. "It can be north up or south up."

Then he took a second ytterbium atom and entangled them. He yoked them together in a quantum sense. The work of Albert Einstein and another physicist, John Bell, says if you can entangle two atoms, then you can prove when they pop out of their simultaneous up-and-down state, they will do so randomly.

"It turns out that quantum entanglement is very hard to come by," Monroe says.

It has been tested with a button that randomly generates series of 0 and 1 numbers.

When some one for instance wants more number ones than zeros, he has bigger chance to get actually more number ones.

And so person can effect on the world:

9QcKDvcnZrE

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Posted

Well that would fit my theory. Richtofen gets something similar to the Casimir Mechanism and instead of making a portal for things to get out of Aether...

THEY GOING IN. But yeah cool information.

Posted

The new wonder grenade u throw looks very massive...and I read in the BO topic on release they said that that grenade thing (I forgot the name) will ether make if easier or harder to kill zombies or something. So it kinda like 50-50 chance thing. Like you have 10 zombie for example and u throw the thing, if it decides to be bad there is 30 zombies now and they are harder for a certain amount of time. But if it decides good maybe it blows up and kills all the zombies in a 30 foot radius. And you get points depending on how many zombie u kill. You know what I'm saying?

Posted

1oS: How does the Quantum Entanglement Device work?

JZ: The answer to what the QED can do can be found in the research of Einstein, Kaluza, Plancke and Klein. That would suggest the possibilities are limitless. Get in the game, throw it out there, and see what it will do FOR YOU.

Max Planck:

German physicist who is regarded as the founder of the quantum theory, for which he received the Nobel Prize in Physics in 1918.

Albert Einstein:

German-born theoretical physicist who developed the theory of general relativity, effecting a revolution in physics. For this achievement, Einstein is often regarded as the father of modern physics and one of the most prolific intellects in human history. He received the 1921 Nobel Prize in Physics "for his services to theoretical physics, and especially for his discovery of the law of the photoelectric effect". The latter was pivotal in establishing quantum theory within physics.

Theodor Kaluza:

German mathematician and physicist known for the Kaluza-Klein theory involving field equations in five-dimensional space. His idea that fundamental forces can be unified by introducing additional dimensions re-emerged much later in string theory.

Felix Klein:

German mathematician, known for his work in group theory, function theory, non-Euclidean geometry, and on the connections between geometry and group theory. His 1872 Erlangen Program, classifying geometries by their underlying symmetry groups, was a hugely influential synthesis of much of the mathematics of the day.

So they all worked with quantum and entanglement and they were all from Germany.

I believe we get more info also on Die Glocke.

The official Quantum Entanglement Device concept art:

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