Soliton Breakthrough For Optical Switching With Frozen Light

At any traffic intersection, one stream of traffic has to stop to let another go through.  This fact of life has limited what can be done with optical switching of data on the internet, since one beam of data-laden light can’t be slowed down to let another though – until now.  From a NIST press release:  Light is so fast that it takes less than 2 seconds to travel from the Earth to the moon. This blazing fast speed is what makes the Internet and other complex communications systems possible. But sometimes light needs to be slowed down so that signals can be routed in the right direction and order, converted from one form to another or synchronized properly.

Now, physicists at the National Institute of Standards and Technology (NIST) have proposed a new way to slow light down to almost one-millionth its usual speed–to the mere speed of a jet aircraft. As described in the Oct. 1 issue of Physical Review Letters, the method eventually could help simplify and reduce the cost of high-speed optical communications. The paper presents mathematical calculations proving the existence of a new class of “soliton,” a solitary light wave that can propagate over long distances without distortion even when moving very slowly through an ultracold gas.

Solitons first were discovered in the 1800s when a naval engineer observed a water wave travel more than a mile within a canal without dissipating. Light wave solitons generated within optical fibers are now the subject of intense research worldwide. Their very short, stable pulse shapes might be used to pack more information into fiber-optic communication systems. But when previously known forms of optical solitons are slowed down, attenuations and distortions (and therefore losses of data) occur quickly, before the light has traveled even 1 millimeter.

NIST physicists showed it is possible to use a very stable pulsed laser to create a soliton that travels slowly through a cryogenic gas of rubidium atoms for more than 5 centimeters without noticeable distortion. The scientists now plan to translate the theory into practical experiments. Currently, 300 kilometers of fiber are required to delay an optical signal for one thousandth of a second, whereas only a few centimeters of fiber might be needed using the new class of soliton.