Using an off-the-shelf inkjet printer, a team of scientists has developed a simple technique for printing patterns of carbon nanotubes on paper and plastic surfaces.
The method, which is described in the August 2006 issue of the journal Small, could lead to a new process for manufacturing a wide range of nanotube-based devices, from flexible electronics and conducting fabrics to sensors for detecting chemical agents. The method was illustrated with an electrically conductive image of Albert Einstein printed on copier paper with carbon nanotube ink.
Carbon nanotubes have enticed researchers since their discovery in 1991, offering an impressive combination of high strength, low weight, and excellent conductivity. But most current techniques to make nanotube-based devices require complex and expensive equipment. “Our results suggest new alternatives for fabricating nanotube patterns by simply printing the dissolved particles on paper or plastic surfaces,” said Robert Vajtai, a researcher with the Rensselaer Nanotechnology Center at Rensselaer Polytechnic Institute and corresponding author of the paper.
Vajtai and his colleagues at Rensselaer — along with a group of researchers led by Krisztián Kordás and Géza Tóth at the University of Oulu in Finland — have developed an approach that uses a commercial inkjet printer to deposit nanotubes onto various surfaces. They simply fill a conventional ink cartridge with a solution of carbon nanotubes dissolved in water, and then the printer produces a pattern just as if it was printing with normal ink. Because nanotubes are good conductors, the resulting images also are able to conduct electricity.
“Printed carbon nanotube structures could be useful in many ways,” Vajtai said. “Some potential applications based on their electrical conductivity include flexible electronics for displays, antennas, and batteries that can be integrated into paper or cloth.” Printing electronics on cloth could allow people to actually “wear” the battery for their laptop computer or the entire electronic system for their cell phone, according to Vajtai.
The approach is simple, versatile, and inexpensive, which makes it superior to other methods for producing conductive surfaces, according to Vajtai. “A great advantage of our process is that the printed patterns do not require curing, which is known to be a limiting factor for conventional conductive ink applications,” he said. “And since our ink is a simple water-based dispersion of nanotubes, it is environmentally friendly and easy to handle and store.”
The researchers plan to continue optimizing the process to improve the quality of the nanotube ink and the conductivity of the printed images. At present, the paper or plastic must be run through the printer multiple times to get an electrically conductive pattern, with the conductivity increasing after each repetition. They also hope to experiment with different chemical modifications to produce a diversity of ink “colours,” each producing surface patterns with different properties, Vajtai said.
Several other Rensselaer researchers collaborated with Vajtai on the project: Pulickel Ajayan, the Henry Burlage Professor of Materials Science and Engineering; Swastik Kar, a postdoctoral research associate in materials science and engineering; Saikat Talapatra, a postdoctoral research associate with the Rensselaer Nanotechnology Center; and Caterina Soldano, a doctoral student in physics, applied physics, and astronomy. From the University of Oulu, Tero Mustonen, Heli Jantunen, and Marja Lajunen also contributed to the research.
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