Inside plastic transistors: crystal-clear window opens on hidden flows.Plastic semiconductors are spawning a new breed of electronic devices that are cheap to make, lightweight, and flexible. The microscopic details of how electric charges move through transistors and other devices made of such materials have remained obscure, however. Now, by creating a new type of transistor from such materials, known as organic semiconductors (SN: 8/30/03, p. 133), Vitaly Podzorov of Rutgers University Rutgers University, main campus at New Brunswick, N.J.; land-grant and state supported; coeducational except for Douglass College; chartered 1766 as Queen's College, opened 1771. Campuses and Facilities Rutgers maintains three campuses. in Piscataway, N.J., and his colleagues there and at the University of Illinois at Urbana-Champaign Early years: 1867-1880 The Morrill Act of 1862 granted each state in the United States a portion of land on which to establish a major public state university, one which could teach agriculture, mechanic arts, and military training, "without excluding other scientific have identified crucial details regarding electric flow through those substances. Charges move more slowly through plastic transistors than they do through transistors based on inorganic semiconductors such as silicon, the stuff of conventional electronics. The new findings indicate that this sluggish rate stems from a ball-and-chain effect: Traveling charges distort the organic materials' malleable malleable /mal·le·a·ble/ (mal´e-ah-b'l) susceptible of being beaten out into a thin plate. mal·le·a·ble adj. 1. Capable of being shaped or formed, as by hammering or pressure. crystal lattices and then have to drag around those distortions. Such understanding of the fundamental behavior of organic semiconductors is vital to the future of the technology, comments Allen Goldman of the University of Minnesota (body, education) University of Minnesota - The home of Gopher. http://umn.edu/. Address: Minneapolis, Minnesota, USA. , Twin Cities. Some flat-screen computer displays already exploit organic semiconductors as light-emitting pixels. However, the range of future uses is expected to mushroom to include such products as electronic newspapers (SN: 1/31/04,p. 67) and digital gadgetry gadg·et·ry n. 1. Gadgets considered as a group. 2. The design or construction of gadgets. Noun 1. gadgetry - appliances collectively; "laborsaving gadgetry" sewn into clothing (SN: 11/20/99, p. 330). Researchers have had a tough time getting a clear picture of how charges move in organic semiconductors. That's because structural defects invariably in·var·i·a·ble adj. Not changing or subject to change; constant. in·var  i·a·bil riddle the thin crystalline films required for making transistors or other devices. Those defects dominate any moving charges' behavior, thereby blinding researchers to the crystal's intrinsic contribution to electronic movement. The Rutgers-Illinois team reports the first organic transistor structure sufficiently free of crystal flaws for the intrinsic behavior of the organic material to stand out. In a yearlong progression of eliminating ever more defects, the researchers have boosted by as much as 200-fold the speed at which charges traverse their transistors. "That's definitely an amazing leap ahead," says Alberto F. Morpurgo of the Delft University of Technology Delft University of Technology, (Technische Universiteit Delft in Dutch) in Delft, the Netherlands, is the largest and most comprehensive technical university in the Netherlands, with over 13,000 students and 2,100 scientists (including 200 professors). in the Netherlands. Made of a thick and uniform crystal of the organic chemical rubrene, the structure also has an insulating gap of air instead of a layer of electrically insulating material, which would initiate defects in the crystal. The team, led by Michael E. Gershenson of Rutgers and John A. Rogers EducationJohn Rogers is a physical chemist at the University of Illinois at Urbana-Champaign. John A. Rogers obtained BA and BS degrees in chemistry and in physics from the University of Texas, Austin, in 1989. of Illinois, describes its work in an upcoming 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. .In their tests, the researchers observed changes in charge speed that theoretical studies and other experimental work have linked to lattice distortions, they say. The new findings are "technically impressive," comments Morpurgo. "Two years ago, [attaining] these results would have been considered science fiction," he says. Although organic semiconductors will probably never pose a speed challenge to silicon, traits such as their flexibility offer important advantages, Podzorov says. To match those advantages with maximum performance, he notes, researchers must figure out how to eliminate crystal defects in the thin-film components actually used in products. |
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