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Image Stored on One Photon

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ROCHESTER, N.Y., Jan, 22, 2007 -- Researchers have made an optics breakthrough that allows them to encode an entire image's worth of data into a photon, slow the image down for storage, and then retrieve the image intact.

While the initial test image consists of only a few hundred pixels, the researchers said a tremendous amount of information can be stored with the new technique, which was developed at the University of Rochester. Howell.jpg
University of Rochester associate physics professor John Howell in the lab. He and his research team have stored an image on a single photon and retrieved it intact.
The image, a "UR" for the University of Rochester, was made using a single pulse of light, and the team can fit as many as a hundred of these pulses at once into a tiny 4-in. cell. Squeezing that much information into so small a space and retrieving it intact opens the door to optical buffering -- storing information as light.

"It sort of sounds impossible, but instead of storing just ones and zeros, we're storing an entire image," said John Howell, associate professor of physics and leader of the team that created the device, which is revealed in today's online issue of the journal Physical Review Letters. "It's analogous to the difference between snapping a picture with a single pixel and doing it with a camera -- this is like a 6-megapixel camera."

SinglePhoton.jpg
The first image encoded, stored and retrieved from a single photon. The right panel is the original image, the panel at left is the image after storage and retrieval.(Images: University of Rochester)
"You can have a tremendous amount of information in a pulse of light, but normally if you try to buffer it, you can lose much of that information," said Ryan Camacho, Howell's graduate student and lead author on the article. "We're showing it's possible to pull out an enormous amount of information with an extremely high signal-to-noise ratio even with very low light levels."

Optical buffering is a particularly hot field right now because engineers are trying to speed up computer processing and network speeds using light, but their systems bog down when they have to convert light signals to electronic signals to store information, even for a short while.

Howell's group used a completely new approach that preserves all the properties of the pulse. The buffered pulse is essentially a perfect original; there is almost no distortion, no additional diffraction, and the phase and amplitude of the original signal are all preserved. Howell is working to demonstrate that quantum entanglement remains unscathed.

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SinglePhotonDiagram.jpg
Experimental setup for the delay of transverse images. Light pulses of 2 ns duration are incident on a 50:50 beamsplitter. The transmitted pulses then pass through an amplitude mask and a 4f imaging system. The transmitted and reflected pulses are recombined at another 50:50 beamsplitter. The transmitted part traverses a path approximately five feet shorter than the reflected path, and arrives at the second beamsplitter about 5 ns sooner than the reflected pulse, preventing interference between the two pulses. The temperature of cesium vapor can then be adjusted to give 5 ns of delay, resulting in interference. In the low-light-level experiment, the pulses are attenuated such that each pulse contains on average less than one photon and the reflected path is blocked. A scanning optical fiber is used to collect the photons in the image plane and the photon arrival times recorded using a photon counter with time-to-digital converter.
To produce the UR image, Howell simply shone a beam of light through a stencil with the U and R etched out, turning down the light so much that a single photon was all that passed through the stencil. Quantum mechanics dictates some strange things at that scale, so that bit of light could be thought of as both a particle and a wave. As a wave, it passed through all parts of the stencil at once, carrying the "shadow" of the UR with it. The pulse of light then entered a 4-in. cell of cesium gas at a warm 100 °C, where it was slowed and compressed, allowing many pulses to fit inside the small tube at the same time.

"The parallel amount of information John has sent all at once in an image is enormous in comparison to what anyone else has done before," said Alan Willner, professor of electrical engineering at the University of Southern California and president of the IEEE Lasers and Optical Society. "To do that and be able to maintain the integrity of the signal -- it's a wonderful achievement."

Howell has so far been able to delay light pulses 100 ns and compress them to 1 percent of their original length. He is now working toward delaying dozens of pulses for as long as several milliseconds, and as many as 10,000 pulses for up to a nanosecond.

"Now I want to see if we can delay something almost permanently, even at the single-photon level," says Howell. "If we can do that, we're looking at storing incredible amounts of information in just a few photons."
 
For more information, visit: www.rochester.edu

Published: January 2007
Glossary
buffer
1. In fiber optics, a protective material applied as an optical fiber cover that has no optical function. 2. In image processing, a peripheral that stores data between two active processing stages.
image
In optics, an image is the reconstruction of light rays from a source or object when light from that source or object is passed through a system of optics and onto an image forming plane. Light rays passing through an optical system tend to either converge (real image) or diverge (virtual image) to a plane (also called the image plane) in which a visual reproduction of the object is formed. This reconstructed pictorial representation of the object is called an image.
light
Electromagnetic radiation detectable by the eye, ranging in wavelength from about 400 to 750 nm. In photonic applications light can be considered to cover the nonvisible portion of the spectrum which includes the ultraviolet and the infrared.
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
photon
A quantum of electromagnetic energy of a single mode; i.e., a single wavelength, direction and polarization. As a unit of energy, each photon equals hn, h being Planck's constant and n, the frequency of the propagating electromagnetic wave. The momentum of the photon in the direction of propagation is hn/c, c being the speed of light.
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
pixel
A pixel, short for "picture element," is the smallest controllable element of a digital image or display. It is a fundamental unit that represents a single point in a raster image, which is a grid of pixels arranged in rows and columns. Each pixel contains information about the color and brightness of a specific point in the image. Some points about pixels include: Color and intensity: In a colored image, each pixel typically consists of three color channels: red, green, and blue (RGB). The...
quantum mechanics
The science of all complex elements of atomic and molecular spectra, and the interaction of radiation and matter.
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