NetComposites Ltd has transferred the rights and ownership of this website to Gardner Business Media Inc.
On 1st January 2020, NetComposites' media assets including netcomposites.com, newsletters and conferences were transferred to Composites World (Gardner Business Media).
This site is no longer being updated. Please direct all enquiries to email@example.com.
For further details see our joint press release.
The continuous fabrication of complex, three-dimensional nanoscale structures and the ability to grow individual nanowires of unlimited length are now possible with a process developed by researchers at the University of Illinois.
Based on the rapid evaporation of solvent from simple “inks,” the process has been used to fabricate freestanding nanofibres, stacked arrays of nanofibres and continuously wound spools of nanowires. Potential applications include electronic interconnects, biocompatible scaffolds and nanofluidic networks.
“The process is like drawing with a fountain pen – the ink comes out and quickly dries or ‘solidifies,’ ” said Min-Feng Yu, a professor of mechanical science and engineering, and an affiliate of the Beckman Institute. “But, unlike drawing with a fountain pen, we can draw objects in three dimensions.”
Yu and graduate students Abhijit Suryavanshi and Jie Hu describe the drawing process in a paper accepted for publication in the journal Advanced Materials, and posted on its Web site.
To use the new process, the researchers begin with a reservoir of ink connected to a glass micropipette that has an aperture as small as 100 nanometres. The micropipette is brought close to a substrate until a liquid meniscus forms between the two. As the micropipette is then smoothly pulled away, ink is drawn from the reservoir. Within the tiny meniscus, the solute nucleates and precipitates as the solvent quickly evaporates.
So far, the scientists have fabricated freestanding nanofibres approximately 25 nanometres in diameter and 20 microns long, and straight nanofibres approximately 100 nanometres in diameter and 16 millimetres long (limited only by the travel range of the device that moves the micropipette).
To draw longer nanowires, the researchers developed a precision spinning process that simultaneously draws and winds a nanofibre on a spool that is millimetres in diameter. Using this technique, Yu and his students wound a coil of microfiber. The microfiber was approximately 850 nanometres in diameter and 40 centimetres long.
To further demonstrate the versatility of the drawing process, for which the U. of I. has applied for a patent, the researchers drew nanofibres out of sugar, out of potassium hydroxide (a major industrial chemical) and out of densely packed quantum dots. While the nanofibres are currently fabricated from water-based inks, the process is readily extendable to inks made with volatile organic solvents, Yu said.
“Our procedure offers an economically viable alternative for the direct-write manufacture of nanofibres made from many materials,” Yu said. “In addition, the process can be used to integrate nanoscale and microscale components.”
The Grainger Foundation, the National Science Foundation and the Office of Naval Research provided funding. Part of the work was carried out in the university’s Center for Microanalysis of Materials, which is partially supported by the U.S. Department of Energy.
For more information visit: