Evidence for self-cleaning in gecko setae

Hansen, Wendy R.; Autumn, Kellar

doi:10.1073/pnas.0408304102

Cited by 553 publications

(440 citation statements)

References 26 publications

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“…Both PSAs and geckos adhere primarily by van der Waals (vdW) forces (Autumn et al 2002;Creton 2003) and have effective elastic moduli below 100 kPa (Dahlquist 1969;Pocius 2002;Autumn et al 2006c), but gecko setae stand in stark contrast to PSAs in their anisotropy ) and self-cleaning (Hansen & Autumn 2005) properties. PSAs are used commonly for both industrial and home applications.…”

Section: Conventional Pressure-sensitive Adhesivesmentioning

confidence: 99%

Frictional and elastic energy in gecko adhesive detachment

Gravish

Wilkinson

Autumn

2007

J. R. Soc. Interface.

127

144

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Geckos use millions of adhesive setae on their toes to climb vertical surfaces at speeds of over 1 m s K1 . Climbing presents a significant challenge for an adhesive since it requires both strong attachment and easy, rapid removal. Conventional pressure-sensitive adhesives are either strong and difficult to remove (e.g. duct tape) or weak and easy to remove (e.g. sticky notes). We discovered that the energy required to detach adhering tokay gecko setae (W d ) is modulated by the angle (q) of a linear path of detachment. Gecko setae resist detachment when dragged towards the animal during detachment (qZ308) requiring W d Z5.0G 0.86 (s.e.) J m K2 to detach, largely due to frictional losses. This external frictional loss is analogous to viscous internal frictional losses during detachment of pressure-sensitive adhesives. We found that, remarkably, setae possess a built-in release mechanism. Setae acted as springs when loaded in tension during attachment and returned elastic energy when detached along the optimal path (qZ1308), resulting in W d ZK0.8G0.12 J m K2 . The release of elastic energy from the setal shaft probably causes spontaneous release, suggesting that curved shafts may enable easy detachment in natural, and synthetic, gecko adhesives.

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Section: Conventional Pressure-sensitive Adhesivesmentioning

confidence: 99%

Frictional and elastic energy in gecko adhesive detachment

Gravish

Wilkinson

Autumn

2007

J. R. Soc. Interface.

127

144

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“…It has been suggested that this same hairy carpet on the gecko feet also plays an important role in self-cleaning. 12 Some of the other systems found in nature that exhibit self-cleaning properties are the leaves of lotus and lady's mantle plants. 18 The surface of lotus leaves have two levels of microscopic roughness ( Figure 1B).…”

mentioning

confidence: 99%

“…17 Even though the surface properties of the spatulas are not known, the hierarchical structure of gecko feet makes the macroscopic structure superhydrophobic. 12 Significant effort in developing synthetic materials inspired by gecko feet show comparable, and in some cases better, shear resistance than natural gecko feet. 2,[6][7][8][9]11 Still, these measurements were done in controlled environments and limited self-cleaning data of these synthetic materials were reported.…”

mentioning

confidence: 99%

Gecko-Inspired Carbon Nanotube-Based Self-Cleaning Adhesives

et al. 2008

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The design of reversible adhesives requires both stickiness and the ability to remain clean from dust and other contaminants. Inspired by gecko feet, we demonstrate the self-cleaning ability of carbon nanotube-based flexible gecko tapes.A gecko has the unique ability to reversibly stick and unstick to a variety of smooth and rough surfaces. The gecko's wall climbing ability, without the use of viscoelastic glue, has attracted significant attention. [1][2][3][4][5][6][7][8][9][10][11] Although the gecko does not groom its feet, its stickiness remains for months between molts. 12 The gecko's dirty feet can recover its ability to climb vertical walls only after a few steps. 12 Our daily experience with sticky tapes has been the opposite. The stickier the adhesive, the more difficult it is to keep it clean from dust and other contaminants. Synthetic self-cleaning adhesives, inspired by the gecko's feet, could be used for many applications including wall climbing robots and microelectronics.The secret of the gecko's adhesive properties lies in the microstructure of gecko feet. 1,[13][14][15] Microscopy shows that gecko feet are covered with millions of small hairs called setae, which further divide into hundreds of smaller spatulas ( Figure 1A). When such a structure is placed against any surface, hairs adapt and allow a very large area of contact with the surface. The van der Waals (vdW) interaction between the hairs and the substrate after contact is sufficient for the gecko to adhere. It has been suggested that this same hairy carpet on the gecko feet also plays an important role in self-cleaning. 12 Some of the other systems found in nature that exhibit self-cleaning properties are the leaves of lotus and lady's mantle plants. 18 The surface of lotus leaves have two levels of microscopic roughness ( Figure 1B). This hierarchical roughness along with a hydrophobic wax coating makes the lotus leaves superhydrophobic. 16,[19][20][21] A water droplet forms a large contact angle with low contact angle hysteresis. This results in the water droplets rolling off the surface, leaving the surface clean. Leaves of a lady's mantle plant have hairs of 10 µm diameter and length of 1 mm ( Figure 1C). It has been suggested that the individual hairs are hydrophilic. However, when acting together on the surface, they make the surface of the leaves superhydrophobic. 17 Even though the surface properties of the spatulas are not known, the hierarchical structure of gecko feet makes the macroscopic structure superhydrophobic. 12 Significant effort in developing synthetic materials inspired by gecko feet show comparable, and in some cases better, shear resistance than natural gecko feet. 2,[6][7][8][9]11 Still, these measurements were done in controlled environments and limited self-cleaning data of these synthetic materials were reported. 7 Recently, we have designed carbon nanotube-based

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“…7 It has also been suggested that the nanowire-structured bristles of gecko feet enable high adhesion to solid and liquid drops arising from the wetting-induced structure rebuilding of the nanowire array. 8,9 Such natural phenomena have inspired materials scientists to more closely examine the wetting behavior of fibrous media, [10][11][12][13] resulting in the development of numerous bio-inspired artificial fibrous systems with special wettability properties. To date, most endeavors have focused on developing either anisotropic fibers for water collection 4,5 and pumping 14 or a vertically aligned fiber array for controllable morphologies through capillarity-induced self-assembly.…”

Section: Introductionmentioning

confidence: 99%

A bio-inspired flexible fiber array with an open radial geometry for highly efficient liquid transfer

et al. 2014

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Generally, highly efficient liquid transfer is difficult to achieve in open fibrous systems, as compared with traditional closed systems, because capillary coalescence frequently occurs when fiber arrays interact with a liquid. Dandelion pappi, which are flexible fiber arrays with open radial geometries, exhibit the unique ability to capture and hold large amounts of water steadily. Drawing inspirations from this natural system, we developed an artificial flexible glass fiber array with a radial geometry that is capable of holding large volumes of liquid and controllably transferring the liquid onto a substrate. The highly efficient liquid transfer of the open fibrous array can be attributed to the synergistic effects of the flexibility of fibers that radially arranged with a big open angle that enables a distinct elastic deformation of the fibers and the consequent formation of a large space within the fiber array for liquid storage, and the highly adhesive property of fibers that helps the pining of three-phase contact line on the fibers. This unique open system may provide a novel strategy for highly efficient and controllable liquid transfer.

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Evidence for self-cleaning in gecko setae

Cited by 553 publications

References 26 publications

Frictional and elastic energy in gecko adhesive detachment

Frictional and elastic energy in gecko adhesive detachment

Gecko-Inspired Carbon Nanotube-Based Self-Cleaning Adhesives

A bio-inspired flexible fiber array with an open radial geometry for highly efficient liquid transfer

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