06.07.16

Growing Graphene Ribbons in One Direction

New method to fabricate graphene nanoribbon arrays on semiconductor wafers turns semimetal into semiconductor.

Click to enlarge photo. Enlarge Photo

Image courtesy of Michael Arnold, University of Wisconsin-Madison

Progressively magnified images of graphene nanoribbons grown on germanium semiconductor wafers. The ribbons automatically align perpendicularly. Scale bars, left to right, are 400, 10, and 1 nanometer.

The Science

Tiny ribbons of a material called graphene could move electricity and dissipate heat more efficiently than silicon in electronic circuits; however, creating the ribbons on traditional supports wasn’t possible. Now, scientists have discovered how to synthesize narrow, long, semiconducting graphene nanoribbons directly on a semiconductor wafer. In this novel synthesis approach, extraordinarily slow growth of the two-dimensional graphene results in unidirectional growth of narrow graphene ribbons with well-defined edges – resulting in the desired transformation of the graphene from a semimetal to a semiconductor.

The Impact

A scalable process for growing semiconducting graphene nanoribbons directly on a semiconductor wafer has been realized. The direct fabrication on conventional semiconductor wafer platforms holds great promise for integrating the graphene nanoribbons into hybrid integrated circuits for energy-efficient electronics and solar cells.

Summary

Graphene nanoribbons are predicted to transport electricity and dissipate heat more efficiently than traditional electronic materials such as silicon. However, the precise fabrication of these semiconducting nanoribbons on conventional wafers has not been possible. Researchers at the University of Wisconsin-Madison have made a scientific breakthrough in understanding how to grow semiconducting nanoribbons directly on conventional germanium wafers. Oriented nanoribbons were grown using a technique called chemical vapor deposition. Under very slow growth conditions, the nanoribbons naturally grew with smooth edges on the surface of a germanium wafer with strongly one-directional growth – aspect ratios for the length compared to the width of the nanoribbon exceeded 70, with the ribbons self-aligning within 6 degrees of each other. The fabrication of aligned arrays of long, narrow graphene nanoribbons (with a tunable width of less than 10 nanometers) directly on conventional semiconductor wafers is compatible with the existing semiconductor-processing infrastructure. This advance may enable the integration of nanoribbons into everyday electronics such as transistors and future, hybrid integrated circuits.

Contact

Michael Arnold
Department of Materials Science and Engineering
University of Wisconsin-Madison
Madison, Wisconsin 53706
michael.arnold@wisc.edu

Funding

This work was primarily supported by the DOE Office of Science (Office of Basic Energy Sciences). This work was partially supported by the Natural Science and Engineering Research Council, the University of Wisconsin, Department of Defense, National Science Foundation, and 3M. This work was performed, in part, at the Center for Nanoscale Materials, a DOE Office of Science User Facility.

Publications

R. Jacobberger, B. Kiraly,  M. Fortin-Deschenes, P. Levesque, K. McElhinny, G. Brady, R. Delgado, S. Roy, A. Mannix, M. Lagally, P. Evans, P. Desjardins, R. Martel, M. Hersam,  N. Guisinger, and M. Arnold, “Direct oriented growth of armchair graphene nanoribbons on germaniumExternal link.” Nature Communications 6, 8006 (2015). [DOI: 10.1038/ncomms9006].

Related Links

UW–Madison ArticleExternal link

Technology Review ArticleExternal link

IEEE ArticleExternal link

Materials Today ArticleExternal link

CS Monitor ArticleExternal link

Nanowerk ArticleExternal link

Tech Times: Article 1External link | Article 2External link

The Engineer ArticleExternal link

EE Times ArticleExternal link

HNGN ArticleExternal link

Highlight Categories

Program: BES, MSE

Performer/Facility: University, DOE Laboratory, SC User Facilities, BES User Facilities, CNM

Additional: Collaborations, Non-DOE Interagency Collaboration, International Collaboration

Last modified: 12/14/2016 4:32:17 PM