A new way of printing electrodes could make touchscreens in phones and other devices work and look better.
The new electrodes, some of the most transparent and conductive ever developed, take advantage of 3D printing to form a grid of gold or silver nanowalls on a glass surface.
The walls are so thin that they can hardly be seen with the naked eye. It is the first time that scientists have created nanowalls like these using 3D printing.
The new electrodes have a higher conductivity and are more transparent than those made of indium tin oxide, the standard material used in smartphones and tablets today. This is a clear advantage: The more transparent the electrodes, the better the screen quality. And the more conductive they are, the more quickly and precisely the touchscreen will work.
“Indium tin oxide is used because the material has a relatively high degree of transparency and the production of thin layers has been well researched, but it is only moderately conductive,” says Patrik Rohner, a PhD student at ETH Zurich who was involved with the research.
How to be transparent and conductive
To create more conductive electrodes, Rohner and colleagues opted for gold and silver, which conduct electricity much better. But because these metals are not transparent, the scientists had to make use of the third dimension.
“If you want to achieve both high conductivity and transparency in wires made from these metals, you have a conflict of objectives. As the cross-sectional area of gold and silver wires grows, the conductivity increases, but the grid’s transparency decreases,” explains Dimos Poulikakos, a thermodynamics professor who led the team.
The solution was to use metal walls only 80 to 500 nanometers thick, which are almost invisible when viewed from above. Because they are two to four times taller than they are wide, the cross-sectional area, and thus the conductivity, is sufficiently high.
The researchers produced these tiny metal walls using a printing process known as Nanodrip, which Poulikakos and his colleagues developed three years ago. Its basic principle is a process called electrohydrodynamic ink-jet printing.
‘We are only printing the tiny droplet’
In this process scientists use inks made from metal nanoparticles in a solvent; an electrical field draws ultra-small droplets of the metallic ink out of a glass capillary. The solvent evaporates quickly, allowing a three-dimensional structure to be built up drop by drop.
What makes the process so unique is that the droplets that come out of the glass capillary are about ten times smaller than the aperture itself. This allows for much smaller structures to be printed.
“Imagine a water drop hanging from a tap that is turned off. And now imagine that another tiny droplet is hanging from this drop—we are only printing the tiny droplet,” Poulikakos says.
The researchers managed to create this special form of droplet by perfectly balancing the composition of metallic ink and the electromagnetic field used.
The next big challenge will now be to upscale the method and develop the print process further so that it can be implemented on an industrial scale. To achieve this, the scientists are working with colleagues from ETH spin-off company Scrona.
They have no doubt that once it is upscaled, the technology will bring a host of advantages compared with existing methods. In particular, it will likely be more cost-efficient, as Nanodrip printing, unlike the production of indium tin oxide electrodes, does not require a cleanroom environment. The new electrodes should also be more suitable for large touchscreens due to their higher conductivity. And finally the process is also the first to allow you to vary the height of the nanowalls directly while printing, says Rohner.
Another possible future application could be in solar cells, where transparent electrodes are also required. The more transparent and conductive they are, the more electricity that can be harnessed. The electrodes could also play a role in the further development of curved display using OLED technology.
This text is published here under a Creative Commons License.
Author: Fabio Bergamin-ETH Zurich
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