Applied electrons make molecules vibrate and move. (Multiple Motions).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. involve billions of individual molecules enacting a complicated dance of bond breaking and formation. In an elegant technical accomplishment that could help researchers better understand these complex interactions, scientists have now choreographed individual molecules to vibrate, break bonds, and move on a surface in specified ways. In the May 29 Nature, an international team of researchers describes how it used the electron-emitting 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. (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 make individual ammonia molecules move in either of two ways. Since the advent of STMs in the 1980s, scientists have used the instruments to produce striking images of surfaces at atomic scales and more recently to push or pull individual atoms and molecules around surfaces. In other experiments, researchers have bombarded molecules with electrons possessing enough energy to detach de·tach v. 1. To separate or unfasten; disconnect. 2. To remove from association or union with something. the molecules from an underlying surface. In the current study, Jose Pascual of the Fritz-Haber-Institut der Max-Planck-Gesellschaft in Berlin and the Institut de Ciencia de Materials de Barcelona-CSIC in Bellaterra, Spain, and his colleagues selectively tweaked See tweak. the vibrations of individual molecules to produce two different movements. To do this, the team used STM electrons with precise energies that excited only one of two types of molecular vibration A molecular vibration occurs when atoms in a molecule are in periodic motion while the molecule as a whole has constant translational and rotational motion. The frequency of the periodic motion is known as a vibration frequency. . That, in turn, primed individual molecules to react in specific ways. The researchers demonstrated the technique with ammonia molecules, which are each made of a nitrogen atom linked to three hydrogen atoms in a pyramidal geometry. When ammonia rests on a copper surface, nitrogen chemically bonds to the copper and the hydrogens stick up. But when Pascual and his colleagues adjust their STM's tip to emit electrons of about 270 millielectronvolts, ammonia molecules that are hit invert in·vert v. 1. To turn inside out or upside down. 2. To reverse the position, order, or condition of. 3. To subject to inversion. n. Something inverted. like an umbrella in the wind. Their hydrogen atoms flip toward the surface, the copper-nitrogen bond breaks, and the molecule pops off the surface. When the researchers used electrons of about 400 millielectronvolts, however, the hydrogen atoms repeatedly stretched apart and pulled back together. This vibration weakened the nitrogen-copper bond, permitting the molecule to slide across the copper surface. This is a pioneering experiment, says Dennis Jacobs of the University of Notre Dame Notre Dame IPA: [nɔtʁ dam] is French for Our Lady, referring to the Virgin Mary. In the United States of America, Notre Dame in Indiana. Pascual's group has shown that it's possible to use STMs with "surgical precision" to dictate the behavior of individual molecules on a surface, he says. Ammonia molecules and copper surfaces don't have special significance, notes Jacobs. Nor are the demonstrated behaviors--desorption from a surface and lateral movement--necessarily useful ones. Rather, he says, the exciting achievement is the technique itself, which may now be applied to a variety of molecules and motions. |
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