One-molecule chemistry gets big reaction.Scientists have long wanted to carry out chemical reactions This is the 18th episode of television drama Men in Trees. It originally aired on June 25, 2007 on the TV2 network in New Zealand as a continuation of season 1. Recap Marin and Cash have a stew cook off, she admits his is better than hers. one molecule at a time. In doing so, they imagined, they would probe the most intimate details of those transformations. Moreover, they've hoped they might find ways to create novel compounds that are impossible to make by conventional means. They also have anticipated assembling molecules that might be useful as nanometer-scale devices, they say. Now, for the first time, researchers numbers have duplicated with individual molecules the full sequence of steps in a widely used chemical reaction. What's more, they've made a photo album of the molecular makeover as it unfolds. Karl-Heinz Rieder, Saw-Wai Hla, and their colleagues at the Free University of Berlin have miniaturized a century-old chemical transformation known as the Ullman reaction. Laboratories and industry use that process to link two iodobenzene molecules, Hla explains. Each contains a six-carbon ring known as a phenyl phenyl (fĕn`əl), C6H5, organic free radical or alkyl group derived from benzene by removing one hydrogen atom. , so a barbell-shaped biphenyl biphenyl /bi·phen·yl/ (-fen´il) diphenyl. polychlorinated biphenyl (PCB) any of a group of chlorinated derivatives of biphenyl, used as heat-transfer agents and electrical insulators; they are results. Normally, the Ullman reaction proceeds in beakers or larger vessels inside which copper, a catalyst, blends countless reacting molecules. Heating the mixture to 400 [degrees] C first breaks off the iodobenzenes' iodine atoms and then forges links between the phenyl rings left behind. Iterations of this reaction can produce multi-ring polymers. In its experiment, the Berlin team began with just two molecules of iodobenzene. These were placed on a copper surface shaped like a step and chilled to 20 kelvins. The researchers then used flows of electrons from the sharp tip of a scanning tunneling microscope 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 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. , to break up the molecules. The tip dragged the fragments around, and its electron bursts provided the energy to rejoin the phenyl rings. Because the STM is able to sense the electron clouds that protrude pro·trude v. 1. To push or thrust outward. 2. To jut out; project. from individual atoms, the researchers also used the instrument to image each step of the reaction. In the end, they checked their work by tugging one ring of the biphenyl product and finding that the other followed along. To his knowledge, says Phaedon Avouris of IBM's T.J. Watson Research Center in Yorktown Heights, N.Y., the new experiment is the first example of "really doing chemistry with the STM" rather than just performing part of a reaction. In 1995, Avouris and his coworkers used electrons from an STM to selectively snip molecular bonds, those between silicon and hydrogen atoms (SN: 6/24/95, p. 391). Last November at Cornell University, physicists Wilson Ho and Hyojune Lee reported the first example of inducing a single atom, iron, and a single molecule, carbon monoxide carbon monoxide, chemical compound, CO, a colorless, odorless, tasteless, extremely poisonous gas that is less dense than air under ordinary conditions. It is very slightly soluble in water and burns in air with a characteristic blue flame, producing carbon dioxide; , to bond--again using an STM. "What's important is that [the German procedure] actually lets us visualize the reaction," adds Ho, now at the University of California The University of California has a combined student body of more than 191,000 students, over 1,340,000 living alumni, and a combined systemwide and campus endowment of just over $7.3 billion (8th largest in the United States). , Irvine. Moreover, this experiment and similar ones that Ho expects to follow will "give us new insights into the nature of chemical bonds and how bonds are formed," he says. In general, these STM manipulations must take place at extremely low temperatures to keep the reactant reactant /re·ac·tant/ (re-ak´tant) a substance entering into a chemical reaction. re·ac·tant n. molecules from randomly hopping around. In the new experiment, the deep chill also squelched squelch v. squelched, squelch·ing, squelch·es v.tr. 1. To crush by or as if by trampling; squash. 2. the thermal energy that drives the breaking and reforming of bonds in a conventional, larger-scale Ullman reaction. The STM electron bursts provided that energy. Now that they have demonstrated molecular manipulation with a familiar reaction, the Berlin researchers have set their sights on molecular constructions never made before, especially ones that might behave like nanometer-scale transistors or other minuscule devices. |
|
||||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion