Published on Thursday October 20, 2011
Drexel scientists have discovered a way to control the flow of electrons between the core and surrounding shell of cylindrical nanowire. This could lead to smaller, more efficient circuitry in electronic devices.
A team of researchers led by associate professor Jonathan Spanier and collaborators in Italy have discovered a new way to manipulate the flow of electrons within different components of a nano-scale material. This new information could lead to the creation of sophisticated circuitry in much smaller scale that would drastically reduce the size of computers and other related technology.
The group has reported on “tuning” the flow of electrons between the core and a surrounding shell of a tiny co-axial cylindrical nanowire. The result is an electrical resistance that is not only negative, but remarkably adjustable, a feature not normally present in individual resistive devices. Integrated circuits, essential to computers and technology for performing complex functions, possess many smaller device elements including those which require a sizable area to store sufficient electric charge.
These new findings, as reported in Physical Review Letters, hold promise for realizing sophisticated functions, such as those involving timing and processing signals, within simple nano-scale components. This result opens the possibility for integrated circuits, essential building blocks of computers, to be constructed with far fewer and smaller components that generate less heat, and waste less energy. “Aside from the potential for nanoscale devices having rich functions, the study also manifests itself as an approach to better understand the interface between materials in the nano-scale,” says Guannan Chen, a Ph.D. student advised by Spanier.
Supported by the National Science Foundation and the U.S. Army Research Office, the team came upon this new information while investigating the flow of electrons through nanowires each consisting of a core and a shell, finding that they could control how and when an excited or “hot” electron relaxes or “cools,” either in the core where the hot electron was produced, or into the neighboring shell. This is what researchers call “tuning” the electron transfer.
"Advanced solar cells include those that harness the excess energy associated with hot electrons that are produced and need to be transferred efficiently when higher-energy photons are incident upon a multi-component nano-scale material,” Spanier says. “By introducing three different ways in which we can independently control electron transfer we have a new framework for investigating the relaxation of hot electrons in nano-scale materials, and in turn, for designing nanostructured solar cells with higher efficiency.”
In addition to Chen, the research team includes Eric Gallo, Oren Leaffer and Terrence McGuckin, Ph.D. students at Drexel and Paola Prete from Consiglio Nazionale delle Ricerche in Lecce, Italy as well as Nico Lovergine from the Unviersity of Salento, also in Lecce, Italy.