New materials boost organic electronics.Over the past decade, research groups in academia and industry have been racing to fabricate electronic devices--integrated circuits, displays for handheld computers, and solar cells--not from silicon but from semiconducting polymers (SN: 5/17/03, p. 312). Components made from such organic materials could be flexible, as well as cheaper and easier to manufacture than their silicon counterparts. Now researchers at Northwestern University Northwestern University, mainly at Evanston, Ill.; coeducational; chartered 1851, opened 1855 by Methodists. In 1873 it absorbed Evanston College for Ladies. in Evanston, Ill., and Lucent Technologies in Murray Hill Murray Hill may refer to one of the following places:
Until recently, the fabrication fabrication (fab´rikā´sh  n),n the construction or making of a restoration. of plastic electronics has been limited by the number of molecular building blocks suitable for making semiconducting polymers. Transistors--which are the switches in an integrated circuit--require two types of semiconductor materials: n-type and p-type. In n-type materials, charge flows through the material via electrons. P-type materials transport charge through "holes," places where electrons are missing. "Yet, most of the organic materials examined so far have all been p-type," says lead investigator Tobin Marks at Northwestern. Existing n-type organics rare and unstable. "So there's a real need for n-type materials," he says. His team's new class of molecules assembles into semiconductors of both p- and n-type. A rod-shaped organic molecule made of six thiophene thi·o·phene n. A colorless liquid, C4H4S, used as a solvent. [thio- + ph(eno)- + -ene. units forms the basis for each type of material. Each thiophene, in turn, is a ring of five carbons and one sulfur. When the researchers replaced the rod's two end thiophenes with a perfluoroarene group (a ring of six carbons decorated with fluorines), the organic molecule behaved like an n-type semiconductor Noun 1. n-type semiconductor - a semiconductor in which electrical conduction is due chiefly to the movement of electrons semiconductor device, semiconductor unit, semiconductor - a conductor made with semiconducting material . When the researchers instead replaced the next two thiophenes from the ends, the molecule behaved as a p-type semiconductor Noun 1. p-type semiconductor - a semiconductor in which electrical conduction is due chiefly to the movement of positive holes semiconductor device, semiconductor unit, semiconductor - a conductor made with semiconducting material . The researchers describe their molecular constructions in the Aug. 25 Angewandte Chemic chem·ic adj. 1. Chemical. 2. Archaic Alchemic. n. Obsolete An alchemist. Adj. 1. International Edition. "It turns out, the way we move the perfluoroarenes around also allows us to control the packing between the molecules," says Marks. The closer the molecules are to each other, the faster a charge can hop from one molecule to another in either type of semiconductor. So far, the team has fabricated prototype transistors from the materials, which performed just as well as existing organic semiconductors do, as measured by the mobility of the electrons and holes. But Marks says his lab expects to increase the n-type material's electron mobility by at least a factor of 5, an advance that would boost the switching speed of the material. The pantry of organic materials for making n-type semiconductors has been particularly sparse, says Ananth Dodabalapur of the University of Texas at Austin “University of Texas” redirects here. For other system schools, see University of Texas System. The University of Texas at Austin (often referred to as The University of Texas, UT Austin, UT, or Texas . "This will be very useful for people like myself who make organic circuits." One of the biggest appeals of plastic electronics is that manufacturers could spray liquid polymer circuits onto a surface using ink-jet printers, instead of resorting to the multibillion-dollar fabrication equipment used to etch circuitry on silicon wafers. Marks predicts that low-cost, even disposable plastic electronic devices, such as smart cards, electronic tags for tracking inventory, and chemical sensors, will emerge in the next couple of years. |
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