Inspired by feet
Geckos, spiders and beetles have shown us how to do it: thanks to special adhesive elements on their feet, they can easily run along ceilings or walls. The science of bionics tries to imitate and control such biological functions, for technological applications and the creation of artificial materials. A research team from Kiel University (CAU) has now succeeded in boosting the adhesive effect of a silicone material significantly. To do so they combined two methods: First, they structured the surface on the micro scale based on the example of beetle feet, and thereafter treated it with plasma. In addition, they found out that the adhesiveness of the structured material changes drastically, if it is bent to varying degrees. Among other areas of application, their results could be interesting for the development of tiny robots and gripping devices. They have been published in the latest editions of the scientific journals Advanced Materials and ACS Applied Materials & Interfaces.
Elastic synthetic materials such as silicone elastomers are very popular in industry. They are flexible, re-usable, cheap and easy to produce. They are therefore used for example as seals, for insulation or as corrosion protection. However, due to their low surface energy, they are hardly adhesive at all. This makes it difficult, for example, to paint silicone surfaces.
Surfaces with a mushroom-like microstructure adhere much better
Professor Stanislav N. Gorb and Emre Kizilkan from the Functional Morphology and Biomechanics working group are researching how to improve the adhesive properties of silicone elastomers. Their example to mimic is the surface structure of certain male leaf beetles (Chrysomelidae), looking like mushrooms. In two recent studies, they discovered that silicone elastomers adhere best if their surface is modified into mushroom-like structures and thereafter specifically treated with plasma. The electrically-charged gas which is the fourth state of matter, alongside solids, liquids and gases. Thus, the researchers combined a geometrical and a chemical method, to imitate biology. In addition, they showed that the degree of curvature of the materials affects their adhesion.
"Animals and plants provide us with a wealth of experience about some incredible features. We want to transfer the mechanisms behind them to artificial materials, to be able to control their behaviour in a targeted manner," said the zoologist Gorb. Their goal of a reversible adhesion in the micro range without traditional glue could make completely new application possibilities conceivable - for example in micro-electronics.
During experimental tests silicones are curved
In a first step, the research team compared silicone elastomers of three different surfaces: one unstructured, one with pillar-shaped elements and a third with a mushroom-like structure. Using a micro-manipulator, they stuck a glass ball onto the surfaces and then removed it again. They tested how the adhesion changes when the materials with microstructured surfaces are bent convex (inwards) and concave (outwards). "In this way, we were able to demonstrate that silicone materials with a mushroom-like structure and curved concave have the double range of adhesive strength," said doctoral researcher Emre Kizilkan, first author of the study. "With this surface structure, we can vary and control the adhesion of materials the most."
Exact parameters for material-friendly plasma treatment
In a second step, the scientists treated the silicone elastomers with plasmas. This method is normally used to functionalise plastic materials, in order to increase their surface energy and to improve their adhesive properties. In comparison with other methods using liquids, plasma treatments can promise greater longevity - however, they often damage the surfaces of materials.
To find out how plasma treatments can significantly improve the adhesion of a material without damaging it, the scientists varied different parameters, such as the duration or the pressure. They found that the adhesion of unstructured surfaces on a glass substrate increased by approximately 30% after plasma treatment. On the mushroom-like structured surface the adhesion even increased by up to 91%. "These findings particularly surprised us, because the structured surface is only half as large as the unstructured, but adhesion enhancement was even three times better after the plasma treatment," explained Kizilkan.
What happens when the treated and non-treated structured surfaces are removed from the glass substrate show the recordings with a high-speed camera: Because of its higher surface energy the plasma-treated microstructure remains fully in contact with the surface of the glass for 50,6 seconds. However, the contact area of the untreated microstructure is reduced quickly by around one third during the removal process, which is why the microstructure completely detaches from the glass substrate after 33 seconds already (Figure 3).
Especially suitable for applications in microelectronics
"We therefore have on a very small area an extremely strong adhesion with a wide range," summarizes the material scientist Kizilkan. This makes the results especially interesting for small-scale applications such as micro-robots. The findings of the Kiel working group have already resulted in the development of an extremely strong adhesive tape, which functions according to the "gecko principle", and can be removed without leaving any residue.
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The studies were conducted within the framework of the Collaborative Research Centre 677 "Function by Switching" at Kiel University.
Photos are available to download:
https://www.uni-kiel.de/fileadmin/user_upload/pressemitteilungen/2018/258-Silikon-1.jpg
Caption: Different configurations change the adhesive effect of the silicone material, whose surface has been given a mushroom-like structure. The adhesion is best when bent concave (right).
© Emre Kizilkan
https://www.uni-kiel.de/fileadmin/user_upload/pressemitteilungen/2018/258-Silikon-2.jpg
Caption: Using a scanning electron microscope, Professor Stanislav N. Gorb (rear) and Emre Kizilkan take pictures of the surface structures with only a few micrometers in size.
© Julia Siekmann
https://www.uni-kiel.de/fileadmin/user_upload/pressemitteilungen/2018/258-Silikon-3.jpg
Caption: Under a scanning electron microscope, the surface of the silicon elastomer with its mushroom-like adhesive elements becomes visible. They are inspired by the microstructures on the feet of certain species of leaf beetles.
© Emre Kizilkan
https://www.uni-kiel.de/fileadmin/user_upload/pressemitteilungen/2018/258-Silikon-4.jpg
Caption: Silicone surfaces treated with plasma (below) have stronger adhesiveness than untreated surfaces (above). The material only separates from the glass surface after 50.4 seconds (I), while the untreated material already separates after 32.8 seconds (D).
© Emre Kizilkan
Originalpublication:
Combined Effect of the Microstructure and Underlying Surface Curvature on the Performance of Biomimetic Adhesives,
Emre Kizilkan and Stanislav N. Gorb
Advanced Materials, Volume30, Issue19, 1704696, 2018
DOI: 10.1002/adma.201704696
https://onlinelibrary.wiley.com/doi/full/10.1002/adma.201704696
Bioinspired Further Enhanced Dry Adhesive by the Combined Effect of the Microstructure and Surface Free-Energy Increase
Emre Kizilkan and Stanislav N. Gorb
ACS Appl. Mater. Interfaces, July 16, 2018
DOI: 10.1021/acsami.8b06686
https://pubs.acs.org/doi/10.1021/acsami.8b06686
Contact:
Professor Stanislav N. Gorb
Zoological Institute at Kiel University
Tel.: +49 (0)431/880-4513
Email: sgorb@zoologie.uni-kiel.de
Web: http://www.uni-kiel.de/zoologie/gorb/topics.html
Emre Kizilkan
Tel.: +49 (0)431/880-4859
Email: ekizilkan@zoologie.uni-kiel.de
Details, which are only a millionth of a millimetre in size: This is what the priority research area "Kiel Nano, Surface and Interface Science - KiNSIS" at Kiel University has been working on. In the nano-cosmos, different laws prevail than in the macroscopic world - those of quantum physics. Through intensive, interdisciplinary cooperation between physics, chemistry science, engineering and life sciences, the research area aims to understand the systems in this dimension and to implement the findings in an application-oriented manner. Molecular machines, innovative sensors, bionic materials, quantum computers, advanced therapies and much more could be the result. More information at http://www.kinsis.uni-kiel.de
Christian-Albrechts-Universität zu Kiel
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