Riddled with Holes: Making Flexible Thin-film Electronics More Durable
작성자. Public Relations Team
Scientists explain how perforating flexible electrodes with micrometer-sized holes makes them resistant to bending and folding
Researchers from Daegu Gyeongbuk Institute of Science and Technology develop a simple approach for controlling the otherwise random formation of cracks in flexible thin-film conductors, greatly increasing the durability of flexible electrodes and transistors against bending and folding.
Professor Jae Eun Jang (back) and Ms. Su Jin Heo (front) next to their experimental setup, with which they observed how cracks formed and propagated in thin flexible conductors with various types of micro-hole arrays.
The prospect of the widespread commercialization and application of flexible electronics has kept researchers worldwide searching for ingenious ways to enhance their performance and durability. From wearable smart devices to solar cells and health sensors, flexible electronics holds much promise in many engineering fields. Unfortunately, flexible devices are usually as fragile as they look; mechanical deformations, such as bending, can induce the formation and propagation of microscopic cracks that ultimately cause devices to fail.
In a recent study, a research team led by Professor Jae Eun Jang from Daegu Gyeongbuk Institute of Science and Technology found a method to greatly improve the durability of thin-film flexible electrodes and transistors, key components in electronics. The method is simple: take your standard flexible conducting film and fill it with micrometer-sized holes in a zigzag pattern.
The researchers actually drew inspiration from civil engineering, as Prof. Jang explains. “We happened to be passing by a construction site, when we saw steel plates with holes, often used in construction. We knew that these steel plates with holes are used to reduce stress. We thought that this method could also be a solution in the micrometer world and, based on this idea, we began conducting experiments.” In the field of mechanics, the word “stress” refers to the forces that the particles of a material exert on each other. External forces increase the stress of a material and can induce the formation of cracks.
In regular thin-film flexible conductors, cracks form in random locations when bent. However, if the flexible conductor bears the array of micrometer-sized holes, the stress distribution of the material changes so that cracks only form at specific points near the edges of the holes and propagate over a short distance. This, as proved through simulations and experiments, allowed their flexible metal electrodes to endure thousands of bending motions. Professor Jang states: “Our devices were able to maintain conductivity up to 300,000 bending cycles, which means that they can be bent over 80 times a day for 10 years.” What’s more, compared with other methods for improving the durability of flexible electronic devices, the proposed approach is inexpensive and easy to adopt using equipment already employed in the display industry.
Repeated bending causes irreparable damage to flexible conductors in the form of microscopic cracks. Developing cost-effective ways of addressing this issue is a prerequisite before flexible electronic devices find their way into our lives.
For more information, contact:
Jae Eun Jang, Professor
Department of Information and Communication Engineering,
Daegu Gyeongbuk Institute of Science and Technology (DGIST)
Gwang Jun Lee, Su Jin Heo, Seungchul Lee, Jae Hoon Yang, Byoung Ok Jun, Hyun Sik Kim, and Jae Eun Jang, "Stress Release Effect of Micro-hole Array for Flexible Electrode and Thin Film Transistor", ACS Applied Materials & Interfaces, Online published on 2 April, 2020.