Physicists have created a hologram using a quantum computer.
The "baby" wormhole was not created with gravity, but through quantumentanglement, the linking of two particles such that measuring one instantly affects the other Physicists were able to create a portal through which they could send information. The hypothesis that our universe is a hologram is supported by the experiment. They published their findings in the journal Nature.
Maria Spiropulu, a physicist at the California Institute of Technology, said at the news conference that this is a baby step for interrogating quantum gravity. I panicked when we saw the data. The people were jumping up and down. I'm trying to not let it get out of hand.
There is a time crystal inside the quantum computer.
Black holes connect hypothetical tunnels through space-time. The gravity of the two black holes is what helps create the conditions of the wormhole, but it is a toy model that relies on a process called quantum teleportation to imitate two black holes and send information through the portal. The processes may not be that different after all. Their experiment might provide the first clues that the theory of gravity that breaks down around black hole singularities could actually emerge from the weird rules governing very small objects like qubits.
Black hole analogues in the quantum computer are not the same as monsters in space The researchers don't know if the simulations they made of the black holes were close enough for them to be considered a variant of the real thing.
It looks like a duck, it walks like a duck, and it makes noise like a duck. "That's what we can say at this point, that's what we're able to say at this point, that's what we're able to say at this point, that's what we're able to say at this point, that's what In terms of the properties we look at, it appears to be a wormhole.
The theory of general relativity, which allowed black holes to be linked in bridges that could connect vast distances, was developed by Albert Einstein and his colleague Nathan Rosen. The goal of the theory was to offer an alternative explanation to the points in space called singularities, where mass has become infinitely concentrated at a single point. General relativity held up if there were wormholes.
Einstein, Rosen and their colleague Boris Podolsky wrote a new paper a month before the 1935 paper. In that research, they made a prediction that, unlike their later paper in general relativity, wasn't meant to bolster quantum theory, but to undermine it. The physicists said that if the rules of quantum mechanics were true, the properties of two particles could become inextricably linked, even if the two were not separated. Einstein derided the process as "spooky action at a distance" but it is now used by physicists.
The two predictions could be connected despite Einstein's dislike for the inherent uncertainty of quantum physics. Physicists have no idea of the realm where gravity and quantum effects collide, such as the interiors of black holes, because of the separation of general relativity and quantum theory.
The search for a theory of everything has led physicists to come up with a lot of different ideas. The hologram principle claims that the universe is a hologram projection of processes on a remote surface.
Stephen Hawking's most challenging theory may be proven correct.
The idea is based on the idea that if black holes emit Hawking radiation, they would eventually evaporate, breaking a rule of quantum mechanics that information cannot be. Despite their many incredibly accurate predictions, general relativity and quantum mechanics are not irreconcilable.
Proponents of string theory used observations that the information contained by a black hole was linked with the 2D surface area of its event horizon in order to solve the problem. The information about the star that collapsed into the black hole was woven into fluctuations on the horizon surface before being sent away.
The idea needn't stop there was realized in the 1990s. The universe could be represented on a 2D event horizon by all the information of a 3D star.
There is a chance that the two theories of general relativity and quantum mechanics are not separated at all. The minute interactions of tiny particles on the lower-dimensional surface of a remote horizon could make space-time appear like a hologram.
The researchers used a bare-bones model of a simple holographic universe that contained two quantum entangled black holes to test their ideas. After decoding an input message into the first qubit, the researchers saw the message get scrambled into gibberish, as if it were swallowed by the first black hole.
If we had two quantum computers that were on different sides of the Earth, you could do an experiment where the quantum information disappeared in our laboratory at Harvard. It would be more impressive than what we did. The physics in both cases are the same.
It's not that the message made it through in some form but that it emerged completely intact and in the same order it went in, which is a key clue to the experiment's nature.
The gap was just a few factors larger than the shortest distance in nature. Experiments of greater complexity, perform them on more advanced hardware and send codes over greater distances are what they want to do in the future. They say it doesn't take much of a theoretical leap to create a mini black hole with a density of qubits.
Spiropulu said that it is very far away. People want to know if they can put their dog in a wormhole. That is a big leap.
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