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Fine-tuning Ultracold Atoms

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COLLEGE PARK, Md., July 20, 2009 – Steps toward both the design of quantum information networks based on ultracold atom gas and the controllable formation of quantum turbulence in ultracold atom gas have been reported.

A quantum network, in which memory devices that store quantum states are interconnected with quantum information processing devices, is a prototype for designing a quantum internet. According to scientists at MIT, one path to making a quantum network is to map light pulses onto nodes in a material system.
Quantum-Memory.jpg

Scientists at MIT have figured out how to relay the successful storage of light in a form of quantum memory based on a cold-atom gas. (Image: Alan Stonebraker/American Physical Society)

While it is one thing to catch a beam of light; it is more difficult to generate a signal that heralds that it has been successfully caught. Quantum systems follow Heisenberg's rule that observing an event may destroy it, so the system has to emit just the right kind of herald pulse so as not to erase the data.

Haruka Tanji, Saikat Ghosh, Jonathan Simon, Benjamin Bloom and Vladan Vuletic from MIT have demonstrated an atomic quantum memory that heralds the successful storage of a light beam in a cold atom gas.

The atomic-ensemble memory can receive an arbitrary polarization state of an incoming photon, called a polarization qubit, announce successful storage of the qubit, and later regenerate another photon with the same polarization state. The herald signal only announces the fact the pulse has been captured, not details of the polarization, so the quantum information is preserved.

This capability will likely benefit scalable quantum networking, where it is crucial to know if operations have succeeded.

In a related discovery, scientists in Brazil have reported the controllable formation of quantum turbulence in an ultracold atom gas. The results may make it easier to characterize quantum turbulence – and potentially even classical turbulence – because it is possible to tune many characteristics of the cold-atom gas.

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Vortices.jpg
Scientists have imaged the vortices that form in the turbulent state of an ultracold atom gas. (Image: E. A. L. Henn/American Physical Society)

Turbulence is considered a nuisance because it slows down boats and jars airplanes. But for hundreds of years, physicists have been fascinated with the notoriously difficult problem of how to describe this phenomenon, which involves the formation and disappearance of vortices – swirling regions in a gas or liquid – over many different length and time scales.

Turbulence can also occur in quantum fluids, such as ultracold atom gases and superfluid helium. In a quantum fluid, the motion of the vortices is quantized; and, because quantum fluids have zero viscosity, the vortices cannot easily disappear.

These properties make quantum turbulence more stable and easier to understand than classical turbulence. Now, Emanuel Henn and colleagues at the University of Sao Paulo in Brazil and the University of Florence in Italy have created quantum turbulence in a gas of ultracold rubidium atoms by shaking it up with a magnetic field. In this way, they are able to control the formation of vortices and generate many different kinds of turbulence to explore a number of questions relevant to both its quantum and classical forms.

Both results are reported in the July 20 issue of Physical Review Letters.

For more information, visit: www.aps.org

Published: July 2009
Glossary
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.
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...
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