CHAMPAIGN, Ill. — New observations could improve industrial production of high-quality graphene, hastening the era of graphene-based consumer electronics, thanks to University of Illinois engineers.
By combining data from several imaging techniques, the team found that the quality of graphene depends on the crystal structure of the copper substrate it grows on. Led by electrical and computer engineering professors Joseph Lyding and Eric Pop, the researchers published their findings in the journal Nano Letters.
“Graphene is a very important material,” Lyding said. “The future of electronics may depend on it. The quality of its production is one of the key unsolved problems in nanotechnology. This is a step in the direction of solving that problem.”
To produce large sheets of graphene, methane gas is piped into a furnace containing a sheet of copper foil. When the methane strikes the copper, the carbon-hydrogen bonds crack. Hydrogen escapes as gas, while the carbon sticks to the copper surface. The carbon atoms move around until they find each other and bond to make graphene. Copper is an appealing substrate because it is relatively cheap and promotes single-layer graphene growth, which is important for electronics applications.
“It’s a very cost-effective, straightforward way to make graphene on a large scale,” said Joshua Wood, a graduate student and the lead author of the paper.
Different crystal shapes are assigned index numbers. Using several advanced imaging techniques, the Illinois team found that patches of copper with higher index numbers tend to have lower-quality graphene growth. They also found that two common crystal structures, numbered (100) and (111), have the worst and the best growth, respectively. The (100) crystals have a cubic shape, with wide gaps between atoms. Meanwhile, (111) has a densely packed hexagonal structure.
“In the (100) configuration the carbon atoms are more likely to stick in the holes in the copper on the atomic level, and then they stack vertically rather than diffusing out and growing laterally,” Wood said. “The (111) surface is hexagonal, and graphene is also hexagonal. It’s not to say there’s a perfect match, but that there’s a preferred match between the surfaces.”
Researchers now are faced with balancing the cost of all (111) copper and the value of high-quality, defect-free graphene. It is possible to produce single-crystal copper, but it is difficult and prohibitively expensive.
The U. of I. team speculates that it may be possible to improve copper foil manufacturing so that it has a higher percentage of (111) crystals. Graphene grown on such foil would not be ideal, but may be “good enough” for most applications.
“The question is, how do you optimize it while still maintaining cost effectiveness for technological applications?” said Pop, a co-author of the paper. “As a community, we’re still writing the cookbook for graphene. We’re constantly refining our techniques, trying out new recipes. As with any technology in its infancy, we are still exploring what works and what doesn’t.”
Next, the researchers hope to use their methodology to study the growth of other two-dimensional materials, including insulators to improve graphene device performance. They also plan to follow up on their observations by growing graphene on single-crystal copper.
“There’s a lot of confusion in the graphene business right now,” Lyding said. “The fact that there is a clear observational difference between these different growth indices helps steer the research and will probably lead to more quantitative experiments as well as better modeling. This paper is funneling things in that direction.”
Lyding and Pop are affiliated with the Beckman Institute for Advanced Science and Technology at the U. of I. The Office of Naval Research, the Air Force Office of Scientific Research, and the Army Research Office supported this research.
Editor's note: To contact Joe Lyding, call 217-333-8370; email: email@example.com.
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Liz Ahlberg, Physical Sciences Editor | 217-244-1073; email@example.com
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