Sun and sand: dirty silicon could supply solar power.Scientists have proposed a way to control the distribution of contaminants in silicon, potentially opening up the use of cheaper, "dirtier" starting materials for making solar cells solar cell, semiconductor devised to convert light to electric current. It is a specially constructed diode, usually made of silicon crystal. When light strikes the exposed active surface, it knocks electrons loose from their sites in the crystal. . In a study published in the September Nature Materials Nature Materials is a monthly multi-disciplinary journal aimed at bringing together cutting-edge research across the entire spectrum of materials science. The journal’s Impact Factor of 19. , the researchers predict that the strategy could lower production costs of solar cells. Silicon is the second most abundant element in Earth's crust crust Outermost solid part of the Earth, essentially composed of a range of igneous and metamorphic rock types. In continental regions, the crust is made up chiefly of granitic rock, whereas the composition of the ocean floor corresponds mainly to that of basalt and gabbro. , but nature's primary sources of silicon--sand and quartz--are tainted taint v. taint·ed, taint·ing, taints v.tr. 1. To affect with or as if with a disease. 2. To affect with decay or putrefaction; spoil. See Synonyms at contaminate. 3. with metals. Converting silicon from these sources into superpure crystals is an expensive and time-consuming process. While there had been enough pure stock for the electronics industry, the needs of the growing photovoltaic The generation of voltage by a material that is exposed to light in the visible and invisible ranges. See photoelectric and photovoltaic cell. industry--which uses silicon for more than 90 percent of its solar cells--caused overall demand to exceed supply in 2004, notes Eicke R. Weber, a materials scientist at 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 and the Lawrence Berkeley (Calif.) National Laboratory. This triggered a drastic price increase in pure silicon, dealing a blow to the solar cell makers. Silicon stock that is less pure and therefore less expensive is available, says Weber. But the increased amounts of iron, copper, and other metal contaminants in these stocks reduce solar cell efficiency. Clusters of these metal atoms attract the solar cell's charge-carrying electrons, reducing the amount of current that the cell can generate. Weber and his colleagues set out to see whether they could minimize the toll taken by these clusters without having to get rid of them. To do this, they turned to Lawrence Berkeley's synchrotron synchrotron: see particle accelerator. synchrotron Cyclic particle accelerator in which the particle is confined to its orbit by a magnetic field. The strength of the magnetic field increases as the particle's momentum increases. , a circular accelerator approximately 65 meters in diameter. The machine generates X rays intense enough to identify within silicon samples individual metal dusters on the order of tens of nanometers in diameter. Weber's team mapped the distribution of the clusters and used a sophisticated technique for measuring how far charges traveled in the samples, an indicator of the material's efficiency in converting sunlight into electricity. The researchers found that silicon hosting larger but fewer numbers of clusters performed better than did samples with smaller but many more clusters. They tested this result by heating samples and then cooling them at different rates, which enabled the researchers to control the distribution of the metal. Weber's team found that silicon with micrometer-size clusters, spaced hundreds of micrometers apart, was four times as efficient as silicon with more-finely-distributed, nanosize clusters. "Without changing the total metal content--only changing the way it is distributed--we get a drastic change in the electrical property" says Weber. "If it is possible to concentrate the metals in a few big clusters, in principle, one can make good solar cells out of ditty dit·ty n. pl. dit·ties A simple song. [Middle English dite, a literary composition, from Old French dite, from Latin dict starting material." "It's excellent work," says Bhushan Sopori, an electrical engineer at the Department of Energy's National Renewable Energy Laboratory The National Renewable Energy Laboratory (NREL), located in Golden, Colorado, as part of the U.S. Department of Energy, is the United States' primary laboratory for renewable energy and energy efficiency research and development. in Golden, Colo. But he cautions that "you often do not have as much control [over metal impurities] as you think" when growing silicon crystals. |
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