Experiment With Chinese Satellite Demonstrates Quantum Weirdness Over Record Distances


Image: Alex Sukontsev/Flickr
Image: Alex Sukontsev/Flickr
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Quantum mechanics is weird as hell, where the rules of the world you experience don’t apply. Even at distances a thousand kilometers apart, particles seem to be able to communicate with each other instantly, for example.

Chinese scientists have subjected this idea to an extreme trial, testing what Albert Einstein has called “spooky action at a distance” between stations receiving light beams from satellites. The research smashes the previous record of around 100 kilometers apart. Don’t expect this sort of stuff to have any influence on your life just yet, but in the future, it could have some important quantum computing applications.

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So, what’s going on?

The mathematics of quantum mechanics comes along with this weird property of entanglement, where particles can take on related properties if they end up in an equation together. If you separate these particles spatially, then they remain entangled with these properties until you observe one of them—then the other particle assumes its corresponding value. It’s as if the fact that you observed the first particle immediately transmits information to the other particle about how it should look.

That’s why Einstein called it spooky action at a distance, because it’s spooky and the particles somehow seem to communicate over a distance. And he didn’t want to believe the effect was real.

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Experiments performed since the 1970s have indeed proven that this spooky action at a distance exists, but these prior tests required optical fibers or other components that weakened the signal. This time around, however, the Chinese team used their newly-launched Micius satellite, which allowed them to send the photons unobstructed through the void of space. They published their result in the journal Science today.

The experiment itself is a really, really roundabout way of performing these observations. The team had several ground stations spread far apart and a satellite. The satellite contains a laser with a device to split the beam, when then passes through a special crystal in order to entangle the pairs of photons. The split beams then travel to two different laboratories, up to 1,200 kilometers (750 miles) apart. The researchers then open up the box at the laboratories and compare.

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Other physicists were impressed, but it’s important to note that only one in six million photons were accurately recovered, Alexander Ling, a physicist at the National University of Singapore told Science. But even this is a huge step above the previous ground-based experiments, the team’s head scientist Jian-Wei Pan from the University of Science and Technology of China in Hefei told Scientific American.

You’re probably wondering what use these satellites would actually have. One possibility is that entangled photons could be important for telecommunications. If someone tried to intercept data sent over one of these quantum lines, the receiver would immediately know, since they’d receive un-entangled data.

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So, technologically, this is a huge step as Jürgen Volz, a physicist at the Vienna Center for Quantum Science and Technology told the LA Times. But it’s still a long, long time before we’ll actually see this technology used in our communications networks.

[Science via Scientific American]

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Science Writer, Founder of Birdmodo

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DISCUSSION

slickromeo
slickromeo

Hypothetical question. Suppose 2 entangled particles are separated (we dont know which way their spin is until observed) ... and they’re separated one thousand miles apart.... so in Quantumn Entanglement.......... detecting the spin of 1 entangled particle (we find out it has up-spin), immediately causes the other entangled particle to have down-spin, and they take a look and wow. it’s true it did have down-spin. and no matter how many times they repeat the experiment, it’s always true that if one is up the other is down, or vice versa if one is down the other is up-spin............ So here’s the question....... why couldn’t we accept that entangled particle1 always had an up-spin, and entangled particle 2 always had a down spin to begin with? but we never knew because we never observed it until the instance of observation?