Less than a micrometre thin, bendable and giving all the colours that a regular LED display does, it still needs ten times less energy than a Kindle tablet. Researchers at Chalmers University of Technology have developed the basis for a new electronic "paper". Their results were recently published in the high impact journal Advanced Materials.
When Chalmers researcher Andreas Dahlin and his PhD student Kunli Xiong were working on placing conductive polymers on nanostructures, they discovered that the combination would be perfectly suited to creating electronic displays as thin as paper. A year later the results were ready for publication. A material that is less than a micrometre thin, flexible and giving all the colours that a standard LED display does.
“The ’paper’ is similar to the Kindle tablet", says Andreas Dahlin. "It isn’t lit up like a standard display, but rather reflects the external light which illuminates it. Therefore it works very well where there is bright light, such as out in the sun, in contrast to standard LED displays that work best in darkness. At the same time it needs only a tenth of the energy that a Kindle tablet uses, which itself uses much less energy than a tablet LED display”.
It all depends on the polymers’ ability to control how light is absorbed and reflected. The polymers that cover the whole surface lead the electric signals throughout the full display and create images in high resolution. The material is not yet ready for application, but the basis is there. The team has tested and built a few pixels. These use the same red, green and blue (RGB) colours that together can create all the colours in standard LED displays. The results so far have been positive, what remains now is to build pixels that cover an area as large as a display.
“We are working at a fundamental level but even so, the step to manufacturing a product out of it shouldn’t be too far away. What we need now are engineers”, says Andreas Dahlin.
One obstacle today is that there is gold and silver in the display, which makes the manufacturing expensive.
“The gold surface is 20 nanometres thick so there is not that much gold in it", says Andreas Dahlin. "But at present there is a lot of gold wasted in manufacturing it. Either we reduce the waste or we find another way to decrease the manufacturing cost”.
Andreas Dahlin thinks the best application for the displays will be well-lit places such as outside or in public places to display information. This could reduce the energy consumption and at the same time replace signs and information screens that aren’t currently electronic today with more flexible ones.
Read the scientific paper Plasmonic Metasurfaces with Conjugated Polymers for Flexible Electronic Paper in Color.
For more information, please contact:
Andreas Dahlin, assistant professor at the Department of Chemistry and Chemical Engineering, Chalmers University of Technology, Sweden, +46 31 772 28 44, firstname.lastname@example.org
Chalmers University of Technology conducts research and offers
education in technology, science, shipping and architecture with a sustainable
future as its global vision. Chalmers is well-known for providing an effective
environment for innovation and has eight priority areas of international
significance – Built Environment, Energy, Information and Communication
Technology, Life Science Engineering, Materials Science, Nanoscience and Nanotechnology,
Production, and Transport.
Graphene Flagship, an FET Flagship initiative by the European Commission, is coordinated by Chalmers. Situated in Gothenburg, Sweden, Chalmers has 10,300 full-time students and 3,100 employees.