Telecommunications

Global quantum internet dawns, thanks to China's Micius satellite

Global quantum internet dawns, thanks to China's Micius satellite
The Micius satellite has sent quantum-encrypted data between China and Austria, bringing the world closer to a global quantum internet
The Micius satellite has sent quantum-encrypted data between China and Austria, bringing the world closer to a global quantum internet
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A teleconference call between the Chinese and Austrian Academies of Sciences was transmitted and encrypted using quantum communications
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A teleconference call between the Chinese and Austrian Academies of Sciences was transmitted and encrypted using quantum communications
Images of scientists Erwin Schrödinger and Micius were transmitted and encrypted through the quantum communication network
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Images of scientists Erwin Schrödinger and Micius were transmitted and encrypted through the quantum communication network
The Micius satellite has sent quantum-encrypted data between China and Austria, bringing the world closer to a global quantum internet
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The Micius satellite has sent quantum-encrypted data between China and Austria, bringing the world closer to a global quantum internet
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Thanks to the internet, a wealth of information is at our fingertips – although the flipside is that sensitive data is often vulnerable to eavesdropping and theft. Quantum encryption can make that literally impossible, and in a new demonstration of that kind of security, scientists have now used the Chinese satellite Micius to send quantum-encrypted data between China and Austria. The experiment brings the world another step closer to a global quantum internet.

Micius was launched in August 2016, to experiment with quantum communications and encryption. Conventional communications satellites transmit information via radio or microwave signals, but Micius uses quantum-entangled photons to effectively "teleport" information. The two photons are inextricably linked, meaning if a user knows the state of one particle they can infer the state of the other, no matter how far apart they are. Last year, Micius smashed the quantum entanglement distance record, sending a message over a distance of 1,200 km (746 mi).

As well as being almost instantaneous, quantum communications are extremely secure. It works in the same way as Schrödinger's famous thought experiment, involving a cat in a quantum superposition of being simultaneously both alive and dead. It's not until an observer peeks into the box and checks on the cat that the superposition collapses into one state or the other.

In quantum key distribution (QKD), a message is sent as individual photons that are in quantum superposition states – in data terms, those photons represent both ones and zeroes at the same time. The message is coded and decoded through devices at each end, which effectively collapse each incoming photon into the required state, one or zero. If an unauthorized person tries to intercept the message along the way, the very act of observing it will cause the superposition of each photon to collapse into a random state, garbling the message for the hacker and alerting the intended recipient to the breach.

Scientists have now used Micius to transmit data encrypted with QKD between Austria and China, over a record distance of 7,600 km (4,722 mi). The satellite first establishes a secure key between itself and one ground station, then another key with another station, and relays the information between the two. In this test, the messages were pictures with file sizes of about 5 kB, using 80-kbit secure quantum keys for one-time-pad encoding.

Images of scientists Erwin Schrödinger and Micius were transmitted and encrypted through the quantum communication network
Images of scientists Erwin Schrödinger and Micius were transmitted and encrypted through the quantum communication network

An image of Micius, the 5th-century Chinese scientist after whom the satellite is named, was sent from Beijing to Vienna, and the reply was an image of Erwin Schrödinger. To up the ante, the scientists then conducted a video conference call between the Chinese and Austrian Academies of Sciences. About 2 GB of data was transmitted during the course of the 75-minute call, including a 560-kbit quantum key. The conference was also encrypted using the Advanced Encryption Standard AES-128, which refreshed the 128-bit seed keys once every second.

The experiments bode well for the roll-out of quantum communication networks on a global scale. Ground-based quantum networks are already in use in some areas such as China, with fibers able to transmit data over a distance of about 100 km (62 mi). With quantum satellites like Micius pitching in, a global quantum internet that's impenetrably secure and lightning fast could be on the horizon.

The research was published in the journal Physical Review Letters.

Source: University of Science and Technology of China

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5 comments
5 comments
MerlinGuy
I thought that quantum entanglement was aiming for two persistent particles that would transmit more than one bit of data without the need of a transmission system. While the entangled photons are amazing, I don't see much of an advance over fiber optics when it comes to transmission. The only benefit is stopping "man-in-the-middle" attacks. If two particles were entangled, persistent, and at different locations then there could be no "man-in-the-middle" or need for encryption. Or did I miss something?
John Kline Kurtz
What keeps an unauthorized person (the enemy) from intercepting and trying to read ALL your messages and therefore interrupting your service?
Brian H
John-- why would you stay online with a broken, garbled link?
Randy Weiss
Transmission of data (or anything) faster than light still seems impossible to my understanding. "Entangled" photons are something like a pair of gloves: A right hand & a left hand glove. If you reach in to a closed box, without looking, take out a wrapped glove, pack it in an envelope and send to China you won't know if you sent or kept the Right hand glove. A week later you look in the box - find only the right hand glove (you kept it, and sent the Left!). In that instant, faster than light, the contents of the sent envelope is known: the Left glove. Nothing travels faster than light. In the quantum internet one must send photons - either thru space or fiber, but still no faster than light speed, for them to be 'unpacked' at the far end.
MarkGatti
yep they are nervous about admitting that the entangled pair are unique so as yet we can't concieve a way to hack into their ' connection', and that the comunication is to our current perception instantaineous....anywere in the known universe ! , rather startling .