Super spinner: seven-atom speck acts like superfluid.Superfluids are weird liquids that flow with no friction and can perform fantastic feats, such as spontaneously crawling over the walls of containers. Theorists have proposed that quantum-mechanical interactions among even a few atoms can give rise to such behaviors. Now, researchers in Canada have evidence for the onset of superfluidity superfluidity, tendency of liquid helium below a temperature of 2.19°K; to flow freely, even upward, with little apparent friction. Helium becomes a liquid when it is cooled to 4.2°K;. in a droplet droplet very small drop of fluid. droplet nuclei the finite particles of matter which are transmitted from animal to animal. containing a mere seven atoms of liquid helium-4. For now, isotopes of helium Helium (He) Standard atomic mass: 4.002602(2) u Natural helium isotopes
Wolfgang Jager and Yunjie Xu of the University of Alberta in Edmonton and A. Robert W. McKellar and Jian Tang of the National Research Council of Canada The National Research Council Canada (NRC) is Canada's leading organization for scientific research and development. History NRC was established in 1916, mainly to advise the government. Then, in the early 1930s, laboratories were built in Ottawa. in Ottawa joined forces to make the discovery. The scientists observed signs of superfluid su·per·flu·id n. A fluid, such as a liquid form of helium, exhibiting a frictionless flow at temperatures close to absolute zero. su behavior in successively larger groupings of helium-4 atoms, starting with three atoms and building up to a cool dozen. In past experiments, other scientists have used a similar approach to demonstrate that superfluidity can appear when as few as 60 helium-4 atoms are present (SN: 4/25/98, p. 271). The Canadian researchers created the helium groupings so that each one was clustered around a molecule of nitrous oxide, better known as laughing gas. Microwave and infrared radiation set the molecule spinning and vibrating. The first six helium atoms to accumulate are essentially dragged along with the rotating molecule at about 10 billion revolutions per second, Jager says. Helium atom number 7, however, altered the picture dramatically. The additional atom not only didn't join the merry-go-round, but its presence also somehow lessened the connections between the other six helium atoms and the nitrous oxide. Slippage started appearing between the spinning molecule and the surrounding helium--a first hint of frictionless flow--and continued with additional helium-4 atoms. Jager, McKellar, and their colleagues report their results in the Oct. 17 Physical Review Letters Physical Review Letters is one of the most prestigious journals in physics.[1] Since 1958, it has been published by the American Physical Society as an outgrowth of The Physical Review. . These new findings may be the first direct observation of superfluidity setting in as helium-4 atoms pile up to form a droplet, Jager says. The observations also illuminate the physical nature of liquid-helium droplets engulfing molecules, he adds. Some theorists regard these minuscule droplets as a mixture of two fluids--a normal fluid and a superfluid. Others argue that the droplets constitute a single superfluid of uneven density. The new data "provide a far more interesting and demanding test of [superfluidity] theory than any previous experiment," says Kevin K. Lehmann Kevin K. Lehmann (b. 7 September 1955 in Newark, New Jersey) is an American chemist and spectroscopist, and a professor of physics and chemistry at the University of Virginia, best-known for his work in the area of intramolecular and collisional dynamics, and for his advances in of Princeton University, a proponent of the single-superfluid point of view. Theorist K. Birgitta Whaley of the University of California, Berkeley The University of California, Berkeley is a public research university located in Berkeley, California, United States. Commonly referred to as UC Berkeley, Berkeley and Cal points out that the new data actually fit nicely with previous theoretical studies based on the two-fluid model. |
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