Explaining Quantum Entanglement with Laser Pointers

Explaining Quantum Entanglement is a Challenge.

Quantum physics to most of us is a very complicated and sometimes counter intuitive science. The concept of quantum entanglement seems like the product of a delusional mind and proving it even more far fetched. Well pull out you laser pointers and see if you can follow as this team explains it.

In a classic eureka moment, a team of physicists led by The City College of New York and including Herriot-Watt University and Corning Incorporated is showing how beams from ordinary laser pointers mimic quantum entanglement with the potential of doubling the data speed of laser communication.

Quantum entanglement is a phrase more likely to be heard on popular sci-fi television shows such as “Fringe” and “Doctor Who.” Described by Albert Einstein as “spooky action at a distance,” when two quantum things are entangled, if one is ‘touched’ the other will ‘feel it,’ even if separated by a great distance.

“At the heart of quantum entanglement is ‘nonseparability’ – two entangled things are described by an unfactorizable equation,” said City College PhD student Giovanni Milione.

Interestingly, a conventional laser beam (a laser pointer)’s shape and polarization can also be nonseparable.

To make the laser beam’s shape and polarization nonseparable, the researchers transformed it into what Milione refers to as a vector beam – a polarization dependent shape. Then using off-the-shelf components to ‘touch’ only its polarization, they showed it could be encoded as two bits of information. Surprisingly, this was twice as much information that could be encoded as when the laser beam was separable.

“In principal, this could be used to double the data speed of laser communication,” said CCNY Distinguished Professor of Phyiscs Robert Alfano.

While there’s no ‘spooky action at a distance,’ it’s amazing that quantum entanglement aspects can be mimicked by something that simple.

About the Research.

An article on the experiment appears in the latest issue of the journal “Optics Letters” and was supported in part by the Army Research Office.

CREDIT Giovanni Milione

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