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Nano Focus: Electron clouds distortion on graphene surface harm conductivity

Published online by Cambridge University Press:  16 August 2011

Abstract

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Other
Copyright
Copyright © Materials Research Society 2011

Graphene, which comprises a single layer of carbon atoms linked in a honeycomb-like arrangement, is highly conductive. However, a research team has produced a series of images that reveal how folds and ripples in this material can limit its conductivity. Under ideal circumstances, when graphene is completely flat, electric charges speed through it without encountering many obstacles, said Sarbajit Banerjee of the State University of New York, Buffalo, one of the researchers who published the study in the June 28 online edition of Nature Communications (DOI: 10.1038/ncomms1376). However conditions are not always optimal.

The images demonstrate that when graphene is folded or bent, the electron cloud lining its surface also becomes distorted. This makes it more difficult for an electric charge to travel through.

Banerjee, D.A. Fischer of the National Institute of Standards and Technology, P.S. Lysaght of SEMATECH, D. Prendergast of the Lawrence Berkeley National Laboratory, and their colleagues used scanning transmission x-ray microscopy and near edge x-ray absorption fine structure (NEXAFS) to create the images, and the experiments were further supported by computer simulations.

“Using simulations, we can better understand the measurements our colleagues made using x-rays, and better predict how subtle changes in the structure of graphene affect its electronic properties,” said Prendergast. “We saw that regions of graphene sloped at different angles, like looking down onto the slanted roofs of many houses packed close together.”

Besides documenting how folds in graphene distort its electron cloud, the research team also discovered that contaminants that cling to graphene during processing linger in valleys created in the material where it is uneven. Such contaminants uniquely distort the electron cloud, thereby changing the strength with which the cloud is bound to the underlying atoms.

Imaging electronic domains in graphene: Dotted lines show distinctive regions of graphene that are sloped at different angles. Soft x-rays paint a bird’s-eye view of the electron cloud of graphene. The image is 4 μm × 4 μm. Photo Credit: Brian J. Schultz.

“It’s not well understood how to transfer graphene onto substrata without it folding onto itself,” Banerjee said. The study suggests that companies hoping to incorporate graphene into products such as conductive inks, ultrafast transistors, and solar panels could benefit from more basic research on the nanomaterial. Improved processes for transferring flat sheets of graphene onto commercial products could greatly increase the efficiency of those materials.