
In yet another small step toward building nanoscale devices, scientists have determined that nanotube peapods — minute straws of carbon filled with spherical carbon molecules known as buckyballs — have tunable electronic properties. Published online by the journal Science,the findings suggest that stuffing the straws provides greater control over the electronic states of single-walled carbon nanotubes (SWNT).
Using a low-temperature scanning tunneling microscope, Ali Yazdani of the University of Illinois at Urbana-Champaign and colleagues imaged the physical structure of individual peapods (right). They mapped the motion of electrons within the pipes and, as Yazdani explains, showed "that an ordered array of encapsulated molecules can be used to engineer electron motion inside nanotubes in a predictable way." Though the harbored buckyballs modify the electronic properties of the nanotube, the atomic structure of the straw remains unchanged.
The researchers also utilized the microscope to move the buckyballs, which allowed them to compare the same section of a SWNT when it was filled and unfilled. "The encapsulated balls have a much stronger effect on the electronic structure of the tube than we had expected," says study co-author Eugene Mele of the University of Pennsylvania. Indeed, the authors conclude that their calculation not only shows how a peapod’s electronic properties differ from those of its constituent parts, "it also provides possible design rules for proposing hybrid structures having a specific type of electronic functionality."
Sarah Graham | Source: Scientific American
Further information: www.sciam.com/news/010402/1.html
More articles from
Materials Sciences:
Scientists Discover Networks of Metal Nanoparticles Are Culprits in Alloy Corrosion
06.08.2008 | Argonne National Laboratory
Smart Contact Lenses
01.08.2008 | University of California - Davis
A world-leading UK science project switches on first neutrons
06.08.2008 | Physics and Astronomy
Electronic tongue tastes wine variety, vintage
06.08.2008 | Life Sciences
Researchers explain odd oxygen bonding under pressure
06.08.2008 | Earth Sciences