Communications of the ACM
Making a One-Way Street For Electricity
Credit: iStockPhoto.com
Circuits have become smaller, letting computers fit in the palm of your hand, but what if circuits could be as small as molecules? To create such circuits, scientists need molecular diodes that let current travel in one direction, but not another. Carbon-based diodes show promise, but they are sensitive to their environment. They don't work well when fit into practical devices. Scientists restructured the diode by separating the electron pipe region, made of a single layer of pentacene, from the metallic electrodes. The buffer is a thin layer of tiny carbon balls, or buckyballs. The new diode is 1,000 times more effective at conducting current in one direction than the other.
Electronics Implications
The scientists identified the molecular Schottky mechanism that lets the diode conduct electricity in one direction and not the other. This mechanism may prove to be a general feature of such molecular systems, and the ability to engineer it through the addition of a thin layer may have implications for mass-producing molecular-based electronics and innovations in solar cells and certain organic photovoltaics.
Desirable Properties
More than forty years after the original proposal of organic molecular diodes, the electrical performance of such devices remains several orders of magnitude below their inorganic counterparts. A primary reason is that molecules are very sensitive to their immediate environment, so that much of their desirable intrinsic electrical properties are lost when integrated into actual devices. Researchers recently overcame such problems by decoupling the active device region made of a monolayer of pentacene from the metallic electrodes using a buffer layer made of metallized buckyballs (C60). They describe their work in "Large Spatially Resolved Rectification in a Donor-Acceptor Molecular Heterojunction," published in the journal Nano Letters.
The inherently weak interactions between C60 and pentacene and the strong coupling of C60 with copper lead to a system reminiscent of a 2-molecule-thick Schottky diode, with a current rectification comparable with the best performers in the field of molecular diodes, the researchers say. These findings open the possibility of engineering non-linear electrical behavior on a nanometer length-scale in organic optoelectronics and photovoltaics.
Scanning tunneling microscopy capabilities at Argonne National Laboratory's Center for Nanoscale Materials (CNM) with surface preparation under ultrahigh vacuum were critical to building and characterizing these self-assembled systems at the atomic scale. With this structure determined experimentally, calculations on the CNM's high-performance computing cluster unraveled the electronic structure and transport mechanism of the heterojunction.
The Nano Letters article is authored by Joseph A. Smerdon of the Jeremiah Horrocks Institute of Mathematics, Physics, and Astronomy at the University of Central Lancashire, United Kingdom, Noel C. Giebink of the Department of Electrical Engineering, The Pennsylvania State University, and Nathan P. Guisinger, Pierre Darancet, and Jeffrey R. Guest of CNM at Argonne National Laboratory.
The researchers' use of the CNM, an Office of Science user facility, was supported by funding from the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under Contract No. DE-AC02-06CH11357. Primary support for this work was provided by the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences Grant DE-FG02-09ER16109. J. A. Smerdon acknowledges support through the U.K. Science and Innovation Network and Department for Business, Innovation, and Skills.
No entries found