1 min readNano-Pea Pod Model Widens Electronics Applications
New York, NY | Heidelberg, Germany — Periodic chain-like nanostructures are widely used in nanoelectronics. Typically, chain elements include the likes of quantum rings, quantum dots, or quantum graphs. Such a structure enables electrons to move along the chain, in theory, indefinitely. The trouble is that some applications require localized electrons—these are no longer in a continuous energy spectrum but in a discrete energy spectrum, instead.
Now, a new study by Russian scientists identifies ways of disturbing the periodicity of a model nanostructure to obtain the desired discrete spectrum with localized electrons. These findings by Dr. Dmitry A. Eremin from the Mordovian State University in Saransk, Russia, and colleagues have been published in EPJ B.
Theoretical calculations on nano-systems play an important role in the prediction of electrical transport properties. The authors created theoretical models of nanometric scale entities dubbed nano-pea pods. The latter are made of a nanotube filled by a chain of fullerene molecules. Such models are based on a bent chain of spheres connected by wires.
The scientists then described the energy spectrum of systems with disturbed periodicity and set out to find the condition for the appearance of localized electrons. Using a method based on the so called general operator extensions theory, they varied the length of the connecting wires, the intensity of the disturbance and the value of the bending angle.
Eremin and colleagues found that localized electrons’ appearance has a stronger dependency on the variation of the length of the wires of the bent chain than the variation of the value of the bending angle. This finding is consistent with the fact that a local perturbation does not affect the continuous spectrum. As the bending angle tends towards zero, the electrons tend to become less localized.
Article adapted from a Springer news release.
Publication: Electron energy spectrum for bent chain of nanospheres. Eremin, D. A. et al. (2014). European Physical Journal (2014): Click here to view.