A new phenomenon discovered in ultracold atoms of a Bose-Einstein condensate (BEC) could offer new insight into the quantum mechanical world and be a step toward applications in "atomtronics"—the use of ultracold atoms as circuit components. Researchers at the National Institute of Standards and Technology (NIST) have reported the first observation of the "spin Hall effect" in a cloud of ultracold atoms.

Atoms in this state occupy the lowest possible quantum state and are then called BEC, which is one of the exotic states of matter. The BEC is one of the younger physical research subjects, with the first BEC experimentally observed in 1995 -- also in a NIST lab.



The spin Hall effect is seen in electrons and other quantum particles when their motion depends on their magnetic orientation, or "spin." Previously, the spin Hall effect has been observed in electrons confined to a two-dimensional semiconductor strip, and in photons, but never before in a BEC. As one consequence of the new discovery, the researchers could make the atoms, which spin like a child's top, skew to one side or the other, by an amount dependent on the spin direction.

A quantum circuit might use spins, described as "up" or "down," as signals, in a way analogous to how electric charge can represent ones and zeros in conventional computers. Quantum devices, however, can process information in ways that are difficult or impossible for conventional devices. Finding ways to manipulate spin is a major research effort among quantum scientists, and the team's results may help the spin Hall effect become a good tool for the job.



The first step for the team was to produce a BEC sample, which is done with several sets of lasers to trap rubidium atoms in a tiny cloud, about 10 micrometers on a side, inside a vacuum chamber and then cool the atoms to a few billionths of a degree above absolute zero. Then, the NIST team employed another laser to gently push the BEC, allowing them to observe the spin Hall effect at work.



Spin is roughly analogous to the rotation of a top, and if the top is gently pushed straight forward, it will eventually tend to curve either to the right or left, depending on which way it is spinning. Similarly, subject to the spin Hall effect, a quantum object spinning one way will, when pushed, curve off to one side, while if it spins the other way, it will curve to the other. The BEC followed this sort of curved path after the laser pushed it.

"This effect has been observed in solids before, but in solids there are other things happening that make it difficult to distinguish what the spin Hall effect is doing," says the research team's Matthew Beeler, who just completed a postdoctoral fellowship at NIST. "The good thing about seeing it in the BEC is that we've got a simple system whose properties we can explain in just two lines of equations. It means we can disentangle the spin Hall effect from the background and explore it more easily."

Conceptually, the laser setup can be thought of as an atom spin transistor—an atomtronic device—that can manipulate spin "currents" just as a conventional electronic transistor manipulates electrical current.

Beeler says that it is unlikely to be a practical way to build a logic gate for a working quantum computer, though. For now, he says, their new window into the spin Hall effect is good for researchers, who have wanted an easier way to understand complex systems where the effect appears. It also might provide insight into how data can be represented and moved from place to place in atomtronic circuits. -- NIST

Paper:



M.C. Beeler, R.A. Williams, K. Jiménez-García, L.J. LeBlanc, A.R. Perry and I.B. Spielman. The spin Hall effect in a quantum gas. Nature, published online June 5, 2013. DOI:10.1038/nature12185.