Sit. Speak. Good Photon!
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Sit. Speak. Good Photon!
Researchers have trapped a laser pulse inside a glass
chamber --and released it again intact. Such command of light
could lead to mind-boggling new technologies.
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March
27, 2002: Light can be hard to handle, yet humans have nearly
mastered it: We can create light (turn on a flashlight) and destroy
it (shine it on black asphalt). We can measure it, bend it, and
slow it down. We can use it to propel spacecraft, to transmit
telephone conversations, to perform surgery. There seems to be
no end to what light can do....
Right: Fiber optics. © Lawrence Manning.
Yet until recently there was one thing we couldn't do
with light: pause it. Stopping light in its tracks and releasing
it again unchanged was beyond human ken.
But now scientists have figured out how to do even that.
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The laser pulse was kilometers-long before it entered the cell, yet the pulse fit intact within the centimeters-wide chamber. Sound like magic? Perhaps ... but it was only quantum mechanics.
Quantum mechanics describes the bizarre rules of light and matter on atomic scales. In that realm, matter can be in two places at once. Objects can be particles and waves at the same time. And nothing is certain -- only probable or improbable.
This improbable feat -- stopping light -- was accomplished by two teams. One was led by Ron Walsworth, a physicist at the Harvard-Smithsonian Center for Astrophysics, and the other by Lene Hau of Harvard University's Department of Physics. Walsworth's group used warm rubidium vapors to pause their laser beam; Hau's group used a super-cold sodium gas to do the same thing.
Below: Before she managed to stop light altogether, Lene Hau and colleagues first slowed it to bicycle speeds in 1999. [more]
Photons
-- that is, particles of light -- are massless, and that's why
they can travel so fast. The Harvard researchers stopped their
laser beams by "weighing the photons down."
The technique requires two lasers: a "control laser" and a "signal laser." The signal laser is the one to be stopped. Using the control laser, Walsworth's team caused rubidium gas in the glass cell to become "dispersive" -- in other words, the velocity of light passing through the gas depended sensitively on the color of the light. (Prisms work much the same way, although the analogy is not exact.) In such a dispersive gas, atoms and photons interact strongly, says Walsworth. "Effectively dragged down by strong interactions with atoms, the photons slowed to a crawl." Physicists call such an atom-photon system a "polariton."
Next they reduced the intensity of the signal laser until the polariton was 100% atomic. There were no photons left inside the chamber. Yet the imprint of the photons remained -- on the atoms themselves. Like a child's top, atoms spin. (Physicists say they "carry angular momentum.") Information describing the fading laser pulse was stored, like a code, in the up-and-down patterns of the atoms' spin axes.
Above: As the laser pulse enters the chamber containing the rubidium vapor, the information that defines the light becomes imprinted on the atoms' spin states (indicated by the small arrows). In the moment that the light is "stopped," only the spin states exist. This image by Tony Phillips is based on another from the American Institute of Physics.
Freeing such a stored pulse is easy: another laser beam directed through the chamber can release it. "In the near future, this technique may enable efficient, reversible mapping of quantum information between light and atoms," says Walsworth.
The possibilities are mind-boggling:
"Suppose you have some information encoded in atoms,"
says Walsworth. "You could map that information onto light,
send it over to some other group of atoms, and imprint the information
there." Walsworth calls this "quantum communication."
Right: Ron Walsworth, Harvard Center for Astrophysics.
Quantum communication might someday be used for sending ultra-secure messages. One of the quintessential traits of the quantum world is that observing a system actually alters that system's properties. In other words, it would be impossible to "touch" a quantum message without leaving "fingerprints."
"So there's no way to intercept messages, break the code, send them on, and have the receiver not know about it," Walsworth says.
Does this seem familiar? It might to fans of Star Trek. Every time Capt. Kirk uses his transporter to visit an alien planet, distant atoms are re-arranged by a beam of something like light to match his body's molecular pattern back on board the Enterprise -- a far-out example of "quantum communication." Star Trek transporters will remain fiction for a long time to come, say researchers. Even so, stopping light might be a tiny first step toward them.
In
the nearer future these techniques might advance a wild new form
of computing called "quantum computing." Futuristic
quantum computers would store data and crunch numbers by manipulating
the quantum states (like spin) of individual atoms. Because of
the vast numbers of atoms in even a thimble-full of matter, quantum
computers could have almost unimaginable power.
Left: A fanciful illustration of qubits.
Courtesy of the Centre for Quantum
Computation.
Computers do their work using binary numbers -- that is, ones
and zeros. Such "bits" are in constant motion inside
your desktop PC. In a quantum computer the bits -- called qubits
-- could be carried from place to place by photons. Horizontal
polarization, for instance, might represent "0" and
vertical polarization "1". (It doesn't end there: Qubits
can be 0, 1, or a superposition of the two -- it's allowed by
quantum physics! Qubits are natural tools for "fuzzy logic."
)
Such a computer would work only if there were some way to stop light, change its state, and send it on its way again. Walsworth's team has demonstrated just such a sequence: While a light pulse was imprinted on the rubidium atoms, they made a simple change to the atoms' quantum states. Much to the researchers' delight, those changes were present in the regenerated light pulse.
Walsworth
and Hau used vapors (rubidium and sodium) to pause light. Will
the insides of quantum computers be vaporous as well?
Right: Supercomputer. © Roger Ressmeyer.
Maybe not: A group led by Phillip Hemmer of Hanscom Air Force Base (he is now at Texas A&M University) has shown that light can be stopped as well by solids. They used a rare-earth doped insulator -- a type of material generally used for ultra-high density optical memories and processors.
"It's very nice to think that it works in a solid state, which is moving more towards the electronics that we're familiar with," Walsworth says.
In a strange new world where scientists can stop light, hold it, and release it at will -- familiar is good.
Walsworth's ongoing research is supported in part by NASA.
Web LinksNASA's Office of Biological & Physical Research -- supports research in fundamental physics.
Stop that Light Beam -- article in Nature Science Update about Lene Hau's research
Light
Stands Still in Atom Clouds --Science News article about the
light-stopping research
At Last! Light Brought to a Halt -- a thorough description of the light-stopping experiment, from the AIP Bulletin of Physics News
Frozen Light: The Tip of the Iceburg -- a detailed and semi-technical article from APS News Online
Right: Lene Hau's science team brought light to a halt in sodium atoms cooled to near absolute zero, the coldest possible temperature (-273°C or -460°F). Hau is pictured top left, along with team members Zac Dutton and Cyrus Behroozi.
The Walsworth Group -- at the Harvard-Smithsonian Center for Astrophysics
Home pages: Ronald Walsworth -- Lene Hau
Centre for Quantum Computing -- learn the basics of quantum computing, for experts and novices alike.
The Science of Star Trek -- Are transporter beams really possible? See also "Where Fact Meets Fiction."
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