New method lights a path for solar cells.Using a technique in which chemical ingredients assemble themselves, a research team has developed a potentially inexpensive way of 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. . So far, high cost has hampered the large-scale use of solar energy solar energy, any form of energy radiated by the sun, including light, radio waves, and X rays, although the term usually refers to the visible light of the sun. systems. Solar cells, also known as photovoltaic cells A semiconductor diode that converts light into DC voltage. Also known as "solar cells," photovoltaic cells are used in a myriad of applications from simple light sensors to complete energy creation systems. See photovoltaic. , transform photons into electric current without producing pollution. Commercially available solar cells already convert sunlight efficiently enough for certain applications, such as satellites, notes J. Devin MacKenzie of the University of Cambridge in England. The widespread use of solar power has been elusive because it can be difficult and costly to manufacture the commercial photovoltaic cells, which are made of inorganic crystals such as silicon, MacKenzie says. Some researchers have tried to circumvent cir·cum·vent tr.v. cir·cum·vent·ed, cir·cum·vent·ing, cir·cum·vents 1. To surround (an enemy, for example); enclose or entrap. 2. To go around; bypass: circumvented the city. this problem by creating photovoltaic cells from organic components that they can process as easily as plastics. Some of these cells remain in various stages of development, but none are close to becoming commercially, successful. In the Aug. 10 SCIENCE, MacKenzie and his colleagues report a development that they say could develop into a particularly simple way of making organic solar cells. Their new cell--which they claim is nearly as efficient as the best organic solar cells already made--contains a liquid crystal called peri-hexabenzocoronene and an organic dye called perylene. When poured onto a flat surface, the ingredients arrange themselves into a two-layered film with an internal structure that promotes electron flow. This simple self-assembly offers a potential new route toward low-cost, mass production of organic solar cells, comments Jenny Nelson of Imperial College in London. Other organic solar cells currently operate a bit more efficiently, she says, but "potentially, [the new technique] could lead to better performance." "This is a beautiful example of combining molecular engineering with nanoscale At nanometer size. Any device only a few nanometers in size is nanoscale. See nanotechnology and nanometer. self-assembly," adds Alan J. Heeger Alan Jay Heeger (born January 22, 1936) is an American physicist, chemist, academic and Nobel Prize laureate in chemistry. Heeger was born in Sioux City, Iowa. He earned his Ph.D in Physics from UC Berkeley in 1961. of the University of California, Santa Barbara History The predecessor to UCSB, Santa Barbara State College, focused on teacher training, industrial arts, home economics, and foreign languages. Intense lobbying by an interest group in the City of Santa Barbara led by Thomas Storke and Pearl Chase persuaded the State and a recent Nobel laureate Noun 1. Nobel Laureate - winner of a Nobel prize Nobelist laureate - someone honored for great achievements; figuratively someone crowned with a laurel wreath for his work on conductive polymers A conductive polymer is an organic polymer semiconductor, or an organic semiconductor. Roughly, there are two classes-- the Charge transfer complexes and the conductive polyacetylenes. (SN: 10/14/00, p. 247). "They have made an important step forward toward the goal of low-cost, high-efficiency, organic photovoltaic cells." In general, organic cells offer certain benefits over inorganic ones, Nelson says. For example, organic cells might be made in different colors and be flexible enough to use on window blinds, walls, and other materials in buildings. This provides design options that could lower the cost of using the cells. High hurdles remain, however. For one, the efficiency of organic solar cells doesn't approach that of the harder-to-make inorganic ones. The best organic cells convert a little more than 2 percent of sunlight into electric current, while commercial inorganic cells reach efficiencies of 20 percent, Nelson says. It remains to be seen whether the new technique, others in development, or a completely unforeseen one will eventually win out, says Nelson. |
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