Atom hauler: molecular rig snags multi-atom loads.A molecule with a knack for picking up and delivering atoms may prove a useful tool for atomic-scale construction. Scientists in France and Germany who created and tested the molecule say that it and similar custom-made structures might aid tasks such as building molecular-scale circuitry, depositing arrays of atom clusters Atom cluster Clusters are aggregates of atoms (or molecules) containing between three and a few thousand atoms that have properties intermediate between those of the isolated monomer (atom or molecule) and the bulk or solid-state material. with special optical or magnetic properties, and cleaning up debris on nanoconstruction sites. For more than a decade, researchers at laboratories equipped with scanning tunneling microscopes scanning tunneling microscope, device for studying and imaging individual atoms on the surfaces of materials. The instrument was invented in the early 1980s by Gerd Binnig and Heinrich Rohrer, who were awarded the 1986 Nobel prize in physics for their work. , or STMs, have pushed around individual atoms. On its own, however, the tiny, extremely sharp tip of an STM (Scanning Tunneling Microscope) A microscope that can image down to the atomic level. An STM uses a piezoelectric tube with a tiny sharp tip at the end that is moved within nanometers of the object being sampled. has trouble maneuvering more than one atom at a time, says Leo Leo, in astronomy Leo [Lat.,=the lion], northern constellation lying S of Ursa Major and on the ecliptic (apparent path of the sun through the heavens) between Cancer and Virgo; it is one of the constellations of the zodiac. Gross, now at IBM (International Business Machines Corporation, Armonk, NY, www.ibm.com) The world's largest computer company. IBM's product lines include the S/390 mainframes (zSeries), AS/400 midrange business systems (iSeries), RS/6000 workstations and servers (pSeries), Intel-based servers (xSeries) Zurich Research Laboratory in Ruschlikon, Switzerland. "With four atoms, it is almost not possible," he notes. Gross and his colleagues used an STM tip to shove the new molecule around on a copper surface. The molecule easily scarfed up as many as five loose copper atoms and then delivered the atom cluster to a desired location, the team reports in the December 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 experiments, which took place at ultra-low temperatures and under high vacuum, were a collaboration between a group--including Gross and led by Francesca Moresco--at the Free University of Berlin and a group led by Christian Joachim of the Center for Materials Elaboration and Structural Studies in Toulouse, France. The scientists designed and synthesized syn·the·sized adj. 1. Relating to or being an instrument whose sound is modified or augmented by a synthesizer. 2. Relating to or being compositions or a composition performed on synthesizers or synthesized instruments. the molecule, known as hexa-t-butyl-hexaphenylbenzene (HB-HBP). It's a hexagon composed of carbon rings. Six tripodlike feet, each known as a t-butyl group, support the structure. This elevated ring structure loosens the copper atoms' bonds with the metal surface. Whereas an STM tip can slide a single unladened HB-HBP molecule over a copper surface with ease, it must push harder with each atom the molecule takes on. Loaded with five copper atoms, the molecule requires much more force but will still move. Add a sixth atom, and it won't budge. To release the cargo, the scientists use the STM tip to lift the HB-HBP molecule. The copper atoms stay behind in a clump. Last year, other researchers reported using cagelike carbon molecules called fullerenes to take up and deposit one to four potassium atoms from a silver surface. The new work goes further, Joachim says, because the scientists designed HB-HBP expressly to carry out atom-hauling chores. Moreover, comments physicist Gerald Dujardin of Universite Paris-Sud in Orsay, France, the finding "opens the way to use a molecule as a real machine" for nanofabrication nan·o·fab·ri·ca·tion n. Any technique used to create objects or mechanisms on the scale of nanotechnology. . Instead of being pushed by an STM tip, such molecular machines could fuel their own movements with light or chemical energy, he says. |
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