Ripples in space: electrons make waves.Drop a pebble in water and what happens? Smooth ripples glide to the water's edge in concentric circles. But what if those ripples hovered as standing waves, in motion yet apparently still? In theory, electrons should form such standing waves when confined in a space of just the right size. Scientists knew roughly how this phenomenon should look, but they had never seen it happen. Now, they can watch quantum theory quantum theory, modern physical theory concerned with the emission and absorption of energy by matter and with the motion of material particles; the quantum theory and the theory of relativity together form the theoretical basis of modern physics. emerge in vivid color. In the Oct. 8 SCIENCE, Michael F. Crommie and his colleagues at IBM's Almaden Research Center The IBM Almaden Research Center, located near San Jose, California, is one of IBM's largest research centers, specializing in both basic research in material science and applied research in computer storage, where many refinements and improvements were made in hard disc drive in San Jose, Calif., report building a quantum corral corral a small fenced-in enclosure with high, wooden fences, suitable for holding cattle or horses. corral system a management system in which range cattle are put into corrals and fed hay for a period when the environment is most , a "round, two-dimensional box" that elegantly shows what quantum theory predicts -- namely, that electrons trapped in a flat, circular space will create standing waves at precise intervals. "Corrals let us actively shape electron wave functions," determining their spatial positions and energy levels, says Donald M. Eigler, and IBM (International Business Machines Corporation, Armonk, NY, www.ibm.com) The world's largest computer company. IBM's product lines include the S/390 mainframes (zSeries), AS/400 midrange business systems (iSeries), RS/6000 workstations and servers (pSeries), Intel-based servers (xSeries) physicist and coauthor of the report. "In this sense, a corral is a remarkable tool." To build the structure, the scientists used a scanning tunneling microscope scanning tunneling microscope, device for studying and imaging individual atoms on the surfaces of materials. The instrument was invented in the early 1980s by Gerd Binnig and Heinrich Rohrer, who were awarded the 1986 Nobel prize in physics for their work. (STM (Scanning Tunneling Microscope) A microscope that can image down to the atomic level. An STM uses a piezoelectric tube with a tiny sharp tip at the end that is moved within nanometers of the object being sampled. ) to individually place 48 iron atoms on a copper surface in a circle roughly 143 angstroms across. Then, using the STM again to sense electron behavior inside the corral, they detected "local densities," which appear as waves, at the very intervals predicted by quantum mechanics quantum mechanics: see quantum theory. quantum mechanics Branch of mathematical physics that deals with atomic and subatomic systems. It is concerned with phenomena that are so small-scale that they cannot be described in classical terms, and it is -- specifically, the Schrodinger equation for a particle in a hard-wall enclosure. The standing waves appear when iron atoms scatter the copper's superface electrons. "Most scientists looking at this image will probably say, 'That's how it should look'," Eigler obseves. "This is not an unexpected result, but rather a unique visual confirmation of what Schrodinger's equations predict." By focusing surface electrons, corrals make possible deeper studies of electron behavior. "We can use corrals to learn much more about how electrons move as guided waves, about how they couple, and perhaps about quantum chaos," says Christopher P. Lutz, another IBM physicist involved in the research. Quantum theory also predicts that, under certain conditions, electrons will move chaotically. To see quantum chaos, the researchers are building corrals with various shapes, such as grids, tubes, and even a "quantum stadium" -- a corral shaped like a running track. Measuring 140 angstroms by 300 angstroms, this flattened ellipse ellipse, closed plane curve consisting of all points for which the sum of the distances between a point on the curve and two fixed points (foci) is the same. It is the conic section formed by a plane cutting all the elements of the cone in the same nappe. will, they hope, create an arena in which electrons can careen chaotically around, again enabling them to test behavior against theory. "The question is how a particle, which also acts as a wave, will behave in the stadium," says Lutz. |
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