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Quantum teleportation demonstrated over existing fiber networks — Deutsche Telekom’s T‑Labs used commercially available Qunnect hardware for the demo, claims 90% average accuracy (www.tomshardware.com)

submitted 15 hours ago by throws_lemy@reddthat.com to c/technology@lemmy.world

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“Teleporting quantum information is now a practical reality,” asserts Deutsche Telekom. The firm’s T‑Labs used commercially available Qunnect hardware to demo quantum teleportation over 30km of live, commercial Berlin fiber, running alongside classical internet traffic. In an email to Tom’s Hardware, Deutsche Telekom’s PR folks said that Cisco also ran the same hardware and demo process to connect data centers in NYC.

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[–] ViperActual@sh.itjust.works 5 points 5 hours ago (1 children)

So there's a lot of incorrect assumptions and outright wrong ideas of how quantum entanglement is going to be used in a quantum network, or even a quantum Internet.

A hard rule: information cannot be sent faster than the speed of light.

When news articles try to summarize quantum teleportation, they incorrectly imply that information is being transmitted instantly. Quantum entanglement is not intended to send information. It's meant to act like a hash or checksum. The magic in it is it enables both sender and receiver to know that their communication has been tampered with.

It has further use with encryption, but again, it's to facilitate the encryption. The information is still being transmitted as light through the fiber network.

[–] FauxLiving@lemmy.world 3 points 5 hours ago (1 children)

Quantum cryptosystems don't move data faster than light but the payload is 'teleported' as in the data isn't sent over the connection.

The entangled states are sent in such a way that when combined with previously transmitted qbits and sampled, the data appears at the receiving end without it ever going through the intermediary (a bit of handwavery because nobody actually understands quantum mechanics, especially physicists.

It is teleportation but not in a way that is FTL, all of the components of the data transmission obey the laws of physics... we just live in a world where the laws of physics allow for some weird and unintuitive shit.

You're not wrong in that the connection's security is absolute, any attempt by an attacker to read the data would disrupt the entangled states in unexpected ways which will result in an essentially random output. So if you're getting data through the link then you know 100% that it is not being intercepted. It isn't possible to copy quantum states for spooky physics reasons, so there is no such thing as a quantum wire tap.

[–] bunchberry@lemmy.world 1 points 20 minutes ago* (last edited 3 minutes ago)

There are nonlocal effects in quantum mechanics but I am not sure I would consider quantum teleportation to be one of them. Quantum teleportation may look at first glance to be nonlocal but it can be trivially fit to local hidden variable models, such as Spekkens' toy model, which makes it at least seem to me to belong in the class of local algorithms.

You have to remember that what is being "transferred" is a statistical description, not something physically tangible, and only observable in a large sample size (an ensemble). Hence, it would be a strange to think that the qubit is like holding a register of its entire quantum state and then that register is disappearing and reappearing on another qubit. The total information in the quantum state only exists in an ensemble.

In an individual run of the experiment, clearly, the joint measurement of 2 bits of information and its transmission over a classical channel is not transmitting the entire quantum state, but the quantum state is not something that exists in an individual run of the experiment anyways. The total information transmitted over an ensemble is much greater can would provide sufficient information to move the statistical description of one of the qubits to another entirely locally.

The complete quantum state is transmitted through the classical channel over the whole ensemble, and not in an individual run of the experiment. Hence, it can be replicated in a local model. It only looks like more than 2 bits of data is moving from one qubit to the other if you treat the quantum state as if it actually is a real physical property of a single qubit, because obviously that is not something that can be specified with 2 bits of information, but an ensemble can indeed encode a continuous distribution.

This is essentially a trivial feature known to any experimentalist, and it needs to be mentioned only because it is stated in many textbooks on quantum mechanics that the wave function is a characteristic of the state of a single particle. If this were so, it would be of interest to perform such a measurement on a single particle (say an electron) which would allow us to determine its own individual wave function. No such measurement is possible.

Dmitry Blokhintsev

Here's a trivially simple analogy. We describe a system in a statistical distribution of a single bit with [a; b] where a is the probability of 0 and b is the probability of 1. This is a continuous distribution and thus cannot be specified with just 1 bit of information. But we set up a protocol where I measure this bit and send you the bit's value, and then you set your own bit to match what you received. The statistics on your bit now will also be guaranteed to be [a; b]. How is it that we transmitted a continuous statistical description that cannot be specified in just 1 bit with only 1 bit of information? Because we didn't. In every single individual trial, we are always just transmitting 1 single bit. The statistical descriptions refer to an ensemble, and so you have to consider the amount of information actually transmitted over the ensemble. The 2 bits of information transmitted each iteration of quantum teleportation, over an ensemble, is plenty enough to capture the continuous state of the qubit, as a single qubit's state only has 2 continuous degrees of freedom.