Hannover Messe: Silver circuits on foil for curved touchscreens
To allow typing and swiping even on curved smartphones, touchscreens and electric conductor paths have also to be curved. Therefore INM has developed a technique which allows fabrication of such conductor lines on flexible foils and even on stretchable silicone. INM will be presenting the so called photochemical metallization on this year’s Hannover Messe.
Mobile phones and smart phones still have not been adapted to the carrying habits of their users. That much is clear to anyone who has tried sitting down with a mobile phone in the back pocket: the displays of such devices are rigid and do not yield to the anatomical forms adopted by the people carrying them. To allow typing and swiping even on curved smartphones, touchscreens and electric conductor paths have also to be curved. Therefore INM – Leibniz Institute for New Materials has developed a technique which allows fabrication of such conductor lines on flexible foils and even on stretchable silicone.
INM will be presenting the so called photochemical metallization on this year’s Hannover Messe at stand B46 in hall 2 from April 23 to 27.
For the proper functioning of touchscreens in smart phones or tablets, microscopically fine conductor lines are required on their surfaces. At the edges of the appliances, these microscopic circuit paths come together to form larger connective pads. Until now, these different lines had to be manufactured in several steps in time-consuming processes. With the photochemical metallization this is now possible in one single step on flexible substrates. The process offers several benefits: It is fast, flexible, variable in size, inexpensive and environmentally friendly. Furthermore additional process steps for post-treatment are not necessary.
In the new process, the foils are coated with a photoactive layer of metal oxide nanoparticles. “After that we apply a colorless, UV-stable silver compound,” Peter William de Oliveira, Head of Optical Materials explains. By irradiation of this sequence of layers, the silver compound disintegrates on the photoactive layer and the silver ions are reduced to form metallic, electrically conductive silver. In this way, lines of varying sizes down to the smallest size of a thousandth of a millimeter can be achieved.
This basic principle allows conductor lines to be created very individually. “There are different possibilities depending on the requirements: Writing conductor lines using UV lasers is the process which is particularly suitable for the initial customized prototype manufacture and for testing a new design of the conductor lines. However, for mass production, this method is too time-consuming,” the physicist de Oliveira explains.
The researchers are currently working intensely on a new method, the usage of transparent stamps. “These stamps push out the silver compound mechanically; conductor lines then only occur where the silver compound remains,” de Oliveira states. Since the stamps are made of a soft plastic, they can be arranged on a roll. Because the stamps are transparent, researchers at INM are now working on embedding the UV source directly in the roll. “Thus, the initial steps for a roll-to-roll process will be taken,” the Head of Optical Materials group concludes. It will therefore be possible to manufacture conductor line structures of various sizes on foils on a large scale.