Teleportation across Calgary marks 'major step' toward creation of 'quantum internet' - Action News
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Teleportation across Calgary marks 'major step' toward creation of 'quantum internet'

In a "major step" toward practical quantum networking, researchers at the University of Calgary have successfully demonstrated the teleportation of a light particle's properties between their lab and the city's downtown area, six kilometres away.

Fibre-optic system between university and city hall enables long-distance 'disembodied' transfer of info

From left, postdoctoral fellows Daniel Oblak, Erhan Saglamyurek and physics professor Wolfgang Tittel, look over lab equipment. Their team recently published a paper on quantum computing advances. (Riley Brandt/University of Calgary)

This story was originally published Sept. 20.


In a "major step"toward practical quantum networking, researchers at the University of Calgary have successfully demonstrated the teleportation of a light particle's properties between their lab and the city's downtown area, six kilometres away.

"What is remarkable about this is that this information transfer happens in what we call a disembodied manner," said physics professorWolfgang Tittel,whose team's work was published this week in the journal Nature Photonics.

"Our transfer happens without any need for an object to move between these two particles."

Their research relies on advanced lasers, a dedicated fibre-optic line, and light-detecting sensors that must be kept incredibly cold becausethey won't work at temperatures above272 C.

It also relies on theincreasingly well-known but still baffling phenomenonof quantum entanglement.

The concept is so bizarre that a dubious Albert Einstein famously dubbed it "spooky action at a distance" in the 1940s, as he described what he saw as flaws in the emerging theory of quantum mechanics.

But today, an increasing body of evidence has confirmed the most counterintuitive predictions of quantum theory, including the strange behaviour of "entangled" particles.

These are pairs of particles that are fundamentally linked, such that the properties of each one is intrinsically tied up in the otherand actions affectingone particle have an immediate effect on the other,no matter how far apart the particles are.

Wolfgang Tittel, professor of physics and astronomy at the University of Calgary, and a group of PhD students have practically demonstrated how to transfer quantum states of photons over a distance of more than six kilometres. (Riley Brandt/University of Calgary)

For their demonstration, the U of C team used a specialized laser tocreatea pair of entangled photons elementary particles of light and sent one to Calgary City Hall via a dedicated fibre-optic line while keeping the other in their lab at the universityin the city's northwest.

At the same time, a third photon was sent to city hall from another location (a data centre in the southeast community of Manchester) so that it would meet and interact withthe entangled photon.

"We had to make sure it arrived at the same time at city hall as the photon that was created at the data centre," said Tittel.

"And that's pretty tricky, because 'the same' in our case means with a provision of a few picoseconds."

(For the non-physics crowd:A picosecond is one-trillionth of a second, or0.000000000001 seconds which meansnot much room for error.)

Tittel said the team had to create feedbackmechanisms in the experimental setupto ensure "very precise timing" of the photons' arrivals at city hall, as small changes in outdoor temperature that cause the fibre-optic cables to expand or contract by minuscule amounts could throw off the timing.

Success from kilometres away

In the end, though, the system worked and the transfer of properties between thephoton at city hall and the photon at the university 6.2kilometres away, as the crow flieswas confirmed.

"It's fascinating to see that, not only teleportation exists, but that you can transfer the state without transferring the photon over a large distance," Tittelsaid.

"From a fundamental point of view, that is fascinating. From a practical point of view, we used a standard fibre network to do so, which of course moves this whole demonstration into the realm of something that will be practical and useful."

The team'sarticle inNature Photonicssays the demonstration "constitutes a milestone towards a global quantuminternet," as it is one of the longest distances over which quantum teleportation has been achieved using a fibre-optic network in this way.

"The way we localized all the different stations within the city of Calgary reflects what needs to be done in a future quantum repeater that will allow us to send quantum information, in principle, over arbitrarily long distances," Tittel said.

"So, it's a major step forward toward that goal."

Coincidentally, in the same edition of the same journal, an independent team of Chinese researchers published the results of their owndemonstration one that used a slightly different setup but employed the same principles and confirmed quantum teleportation using a fibre-optic network over a span of 12 kilometres.

"Our experiment marks a critical step towards the realization of a global 'quantum internet' in the real world," the Chinese teamwrote.

What is the 'quantum internet,' anyway?

It doesn't exist yet, but the dreamof a "quantuminternet" involves taking advantage of a key element ofquantum mechanicsthe fact that observing a particle's quantum state changes thatparticle's quantum state.

Thiscreates the opportunity to communicate with a degree of security never before possible, because no one can intercept a communication without the intended receiver of the information knowing about it.

"If you encode keys into quantum states and send them from person to anotherfor instance, throughteleportationthen it turns out that you can verify at the receiver's side if an eavesdropper has acquired any information about that key,"Tittelsaid.

"If you find out that nobody has tampered with this transmission, you know that you share a perfectly secure key and then you can use it to encrypt some sensitive data."

Partnership between university, municipality

The development of functional quantum networksis still a long time off, butSylvain Mayer, an information architecture engineer with theCity of Calgary, said the city plans to continue working with the universityto speed up the process.

The fibre-optic network the U of C team used normallycarries information between various city departments, but a dedicated portion of it was made available to the researchers through the Urban Alliance, a partnership developed in 2007.

"We're happy that part of our fibre infrastructure can be used by these fellows to be able to research cutting-edge technology," Mayer said.

"The city just wants to be able to continue to be able to help educational institutions in their pursuit of next-generation types of services that will eventually be able to help everyone around the world."