AI Article Synopsis
- Geckos' ability to climb is due to a unique combination of microscopic structures and stiff materials (β-keratin), allowing for reliable adhesion.
- The challenge in engineering similar dry adhesives is the difficulty of creating high-aspect-ratio structures with stiffer polymers.
- Researchers successfully fabricated these structures on flexible polycarbonate sheets and demonstrated their effective use in a miniature robot, showcasing strong adhesion and durability over multiple cycles.
Article Abstract
The unusual ability of geckos to climb vertical walls underlies a unique combination of a hierarchical structural design and a stiffer material composition. While a dense array of microscopic hierarchical structures enables the gecko toe pads to adhere to various surfaces, a stiffer material (β-keratin) composition enables them to maintain reliable adhesion over innumerable cycles. This unique strategy has been seldom implemented in engineered dry adhesives because fabrication of high-aspect-ratio hierarchical structures using a stiffer polymer is challenging. Herein, we report the fabrication of high-aspect-ratio hierarchical arrays on flexible polycarbonate sheets (stiffness comparable to that of β-keratin) by a sacrificial-layer-mediated nanoimprinting technique. Dry-adhesive films comprising the hierarchical arrays showed a formidable shear adhesion of 11.91 ± 0.43 N/cm. Cyclic adhesion tests also showed that the shear adhesion of the adhesive films reduced by only about 20% after 50 cycles and remained nearly constant until about 200 cycles. Most importantly, the high-aspect-ratio hierarchical arrays were integrated onto the feet of a miniature robot and the locomotion on a 30° inclined surface was demonstrated.
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| http://dx.doi.org/10.1021/acsami.7b09526 | DOI Listing |
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