Carpet of carbon nanotubes cleans itself.The amazing water-shedding ability of the lotus leaf has long inspired materials scientists. The leaf's wax-coated microstructures cause rain droplets to bounce off the surface, carrying away with them dust particles and other contaminants. In trying to reproduce this so-called lotus effect The lotus effect in material science is the observed self-cleaning property found with lotus plants. In some Eastern cultures, the lotus plant is a symbol of purity. Although lotuses prefer to grow in muddy rivers and lakes, the leaves and flowers remain clean. in the lab, chemical engineers have fabricated fab·ri·cate tr.v. fab·ri·cat·ed, fab·ri·cat·ing, fab·ri·cates 1. To make; create. 2. To construct by combining or assembling diverse, typically standardized parts: a similar self-cleaning material out of forests of carbon nanotubes. Led by Karen Gleason of the Massachusetts Institute of Technology Massachusetts Institute of Technology, at Cambridge; coeducational; chartered 1861, opened 1865 in Boston, moved 1916. It has long been recognized as an outstanding technological institute and its Sloan School of Management has notable programs in business, (MIT MIT - Massachusetts Institute of Technology ), the researchers first created arrays of tiny islands of nickel on a surface of silicon. >From these islands, the researchers grew vertically aligned carbon nanotubes. "Sort of like a bed of pins" is how coinvestigator Kenneth Lau describes the result. The minuscule pillars, each measuring 50 nanometers in diameter and standing 2 micrometers, form a rough surface. Because there are air pockets between the nanotubes, when a drop of water lands on the surface, "it's essentially held up by air," says Lau. Using a technique called chemical vapor deposition Vapor deposition Production of a film of material often on a heated surface and in a vacuum. Vapor deposition technology is used in a large variety of applications. , the researchers coated the top of each carbon nanotube with poly(tetrafluoroethylene Noun 1. tetrafluoroethylene - a flammable gaseous fluorocarbon used in making plastics (polytetrafluoroethylene resins) fluorocarbon - a halocarbon in which some hydrogen atoms have been replaced by fluorine; used in refrigerators and aerosols ), otherwise known as Teflon. Not only did this arrangement stabilize the nanotube A carbon molecule that resembles a cylinder made out of chicken wire one to two nanometers in diameter by any number of millimeters in length. Accidentally discovered by a Japanese researcher at NEC in 1990 while making Buckyballs, they have potential use in many applications. forest, but it also boosted the surface's waterrepelling properties. When water droplets squeezed from a syringe hit the Tefloncoated nanotube carpet, the droplets bounced from and rolled off the surface. Because the spacing between nanotubes was less than a micron, the material could repel tiny droplets of water just a few micrometers in diameter. The researchers describe the new material in a forthcoming issue of Nano Letters. Materials such as these are called superhydrophobic because of their ability to repel water so completely. On more standard hydrophobic hydrophobic /hy·dro·pho·bic/ (-fo´bik) 1. pertaining to hydrophobia (rabies). 2. not readily absorbing water, or being adversely affected by water. 3. surfaces, such as the hood of a car, water droplets form flatterbottomed spheres that might not roll off. Researchers throughout the world have been striving to invent superhydrophobic materials for products such as antifouling paint Noun 1. antifouling paint - a paint used to protect against the accumulation of barnacles etc. on underwater surfaces paint, pigment - a substance used as a coating to protect or decorate a surface (especially a mixture of pigment suspended in a liquid); dries to , self-cleaning garments, or coatings on airplanes to prevent ice buildup. In pursuit of that goal, investigators have tried a variety of polymer fibers and spheres (SN: 3/1/03, p. 132). So far, however, the resulting materials have been too fragile to be practical. To join the competition, the MIT group turned to one of nanotechnology's poster materials, carbon nanotubes. "Coating the nanotubes with [Teflon] is very neat and novel," says A. Levent Demirel, a chemist at Koc University in Istanbul, Turkey. Without the Teflon, the water droplets would eventually seep through the material. David Quere, a chemist at the College de France in Paris, says the nanotube route to superhydrophobic materials is attractive, but he isn't yet convinced it will lead to commercial products. Even though the Teflon coating stabilizes the nanotubes, he says, "if you press your thumb on them, you immediately destroy the structures." |
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