Hot stuff: a usually ultracold, odd state forms when warm.An exotic quantum state that had previously appeared only under conditions of astonishing a·ston·ish tr.v. as·ton·ished, as·ton·ish·ing, as·ton·ish·es To fill with sudden wonder or amazement. See Synonyms at surprise. cold has made its room-temperature debut, reports an international team of scientists. In related experiments, other researchers have produced a similar state in different, still-chilly materials but claim that their experiments will lead to room-temperature versions as well. The new findings, unveiled in independent reports in the Sept. 28 Nature, reveal a bizarre new branch of an already exotic family of quantum states of matter known as Bose-Einstein condensates. Previously produced Bose-Einstein condensates, which form only at temperatures near absolute zero, include a 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 of liquid helium that flows with no friction (SN: 2/26/05, p. 142) and condensates of dilute gases (SN: 1/17/04,p. 35). Superconductors, which are materials that permit electric current to flow without resistance at ultracold temperatures (SN: 4/1/06, p. 196), exhibit many of the properties of Bose-Einstein condensates, but physicists disagree on whether those materials precisely fit the condensate's definition. The newest findings might make quantum-physics experiments easier by eliminating tricky cryogenics cryogenics: see low-temperature physics. cryogenics Study and use of low-temperature phenomena. The cryogenic temperature range is from −238°F (−150°C) to absolute zero. At low temperatures, matter has unusual properties. and might lead to practical payoffs such as extremely low-power lasers. The two new demonstrations also buoy scientists' expectations that they'll someday find a way to dramatically raise the temperatures required for superconductor A material that has little resistance to the flow of electricity. Traditional superconductors operate at absolute zero (-459.67 degrees Fahrenheit or -273.15 degrees Celsius). Experiments in the 1980s raised the temperature to -321 degrees Fahrenheit. operation--an achievement that could lead to enormous energy savings. Room-temperature superconductivity superconductivity, abnormally high electrical conductivity of certain substances. The phenomenon was discovered in 1911 by Kamerlingh Onnes, who found that the resistance of mercury dropped suddenly to zero at a temperature of about 4.2°K;. is "definitely at the back of people's minds," notes David Snoke, a University of Pittsburgh physicist who also does research on novel Bose-Einstein condensates (http:// blogs.nature.com/nature/peerreview/trial/). However, he adds, the means to achieve such superconductivity remain unclear. Bose-Einstein condensates typically form when falling temperatures induce the atoms of a gas or other particles to exhibit their wavelike quantum nature and grow larger, as dictated by Heisenberg's uncertainty principle. The expanding waves then overlap and meld into, in essence, a single object--the condensate. In both the new reports, however, the experimenters used means other than extreme cold to make the condensates. The starting materials, which had not previously been formed into condensates, were what physicists call quasiparticles. According to Sergej O. Demokritov of the University of Munster in Germany, quasiparticles are ephemeral energy excitations that come and go inside solid materials, somewhat like the crests of waves in an ocean do. Quasiparticles can collide and exchange velocity as billiard bil·liard adj. Of, relating to, or used in billiards. n. See carom. Adj. 1. billiard - of or relating to billiards; "a billiard ball"; "a billiard cue"; "a billiard table" balls do and otherwise behave fleetingly like standard particles, he notes. In the set of experiments conducted at room temperature, Demokritov and his colleagues zapped a thin film of the magnetic compound yttrium iron garnet Yttrium iron garnet (YIG) is a kind of synthetic garnet, with chemical composition Y3Fe2(FeO4)3, or Y3Fe5O12. It is a ferrimagnetic material with Curie temperature 550 K. that they had placed in a device akin to a microwave oven. The treatment boosted the film's population of quasiparticles known as magnons. In the other, much lower-temperature experiments, physicist Benoit Deveaud-Pledran of the Ecole Polytechnique Federale de Lausanne in Switzerland and his colleagues fired a laser at a microstructure mi·cro·struc·ture n. The structure of an organism or object as revealed through microscopic examination. microstructure Noun a structure on a microscopic scale, such as that of a metal or a cell made of the semiconductor cadmium telluride. In the material, the procedure produced quasiparticles called exciton Exciton A fundamental quantum of electronic excitation in condensed matter, consisting of a negatively charged electron and a positively charged hole bound to each other by electrostatic attraction. polaritons, which form when photons of light and electrons collide. In each experimental run, the elevated quasiparticle Noun 1. quasiparticle - a quantum of energy (in a crystal lattice or other system) that has position and momentum and can in some respects be regarded as a particle densities caused the wavelike entities to overlap and form condensates, the investigators say. In a commentary published with the reports, Snoke says that the magnon-making study, while promising, lacks firm evidence that the magnetic waves exactly match each other as they should in a condensate. Demokritov says that in additional experiments, his team has demonstrated that the waves match. |
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