Water transport mechanism through open capillaries analyzed by direct surface modifications on biological surfaces

Ishii, Daido; Horiguchi, Hiroko; Hirai, Yuji; Yabu, Hiroshi; Matsuo, Yasutaka; Ijiro, Kuniharu; Tsujii, Kaoru; Shimozawa, Tateo; Hariyama, Takahiko; Shimomura, Masatsugu

doi:10.1038/srep03024

Cited by 46 publications

(46 citation statements)

References 18 publications

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“…Many natural systems have evolved into functional surfaces to achieve water transport for survival, [1][2][3][4][5][6][7][8][9][10] for example, the back of desert beetles, [1] shorebird beaks, [3] spider silk, [5] and cactus spines. [6] Without energy input, these biological surfaces can harness the movement of water through their unique structural features and chemical composition, [11][12][13] which gives inspiration for designing and fabricating functional surfaces and materials with wide applications in fields including antifogging and fog-collection, [14][15][16] microfluidic devices, [17][18][19][20][21] lubrication, [22,23] and liquid transport.…”

Section: Introductionmentioning

confidence: 99%

Surfaces Inspired by the Nepenthes Peristome for Unidirectional Liquid Transport

Zhang

Chen

et al. 2017

Advanced Materials

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The slippery peristome of the pitcher plant Nepenthes has attracted much attention due to its unique function for preying on insects. Recent findings on the peristome surface of Nepenthes alata demonstrate a fast and continuous unidirectional liquid transport, which is enabled by the combination of a pinning effect at the sharp edges and a capillary rise in the wedge, deriving from the multiscale structure, which provides inspiration for designing and fabricating functional surfaces for unidirectional liquid transport. Developments in the fabrication methods of peristome‐inspired surfaces and control methods for liquid transport are summarized. Both potential applications in the fields of microfluidic devices, biomedicine, and mechanical engineering and directions for further research in the future are discussed.

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Section: Introductionmentioning

confidence: 99%

Surfaces Inspired by the Nepenthes Peristome for Unidirectional Liquid Transport

Zhang

Chen

et al. 2017

Advanced Materials

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“…Capillary liquid transport can take place in small cavities, such as tubes, ridges or channels, where the capillary forces dominate other major contributing forces such as viscosity, friction or gravitational force (Berthier and Silberzan, 2010). Corresponding surface structures can be found in the granular skin of some toads and elephants (Lillywhite and Licht, 1974;Lillywhite and Stein, 1987), surface channels of moisture-harvesting lizards (Gans et al, 1982;Withers, 1993;Veselý and Modrý, 2002;Sherbrooke et al, 2007;Comanns et al, 2015), flat bugs and wharf roaches (Hoese, 1981;Horiguchi et al, 2007;Ishii et al, 2013), and cavities between feather structures of sandgrouse (Rijke, 1972;Joubert and MacLean, 1973;Rijke and Jesser, 2011). In the case of moisture-harvesting lizards, transportation in channels avoids wetting much of the body surface and hence losing volume by evaporation from a larger area (Comanns et al, 2011;Yenmisȩ t al., 2015).…”

Section: Capillary Transport Of Watermentioning

confidence: 99%

“…Further examination has revealed more detail: hair-and paddle-like microstructures on two neighboured legs (i.e. pereiopods VI and VII) collect and transport the adhered water; the water is then transported further along the swimming limbs ( pleopods) and to the hindgut, near the anus, for uptake by absorption (Horiguchi et al, 2007;Ishii et al, 2013). Collected water also establishes a water film on the integument and evaporation is regularly used for thermoregulation (Hoese, 1981).…”

Section: Capillary Transport Of Watermentioning

confidence: 99%

Passive water collection with the integument: mechanisms and their biomimetic potential

Comanns

2018

Journal of Experimental Biology

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Several mechanisms of water acquisition have evolved in animals living in arid habitats to cope with limited water supply. They enable access to water sources such as rain, dew, thermally facilitated condensation on the skin, fog, or moisture from a damp substrate. This Review describes how a significant number of animals - in excess of 39 species from 24 genera - have acquired the ability to passively collect water with their integument. This ability results from chemical and structural properties of the integument, which, in each species, facilitate one or more of six basic mechanisms: increased surface wettability, increased spreading area, transport of water over relatively large distances, accumulation and storage of collected water, condensation, and utilization of gravity. Details are described for each basic mechanism. The potential for bio-inspired improvement of technical applications has been demonstrated in many cases, in particular for several wetting phenomena, fog collection and passive, directional transport of liquids. Also considered here are potential applications in the fields of water supply, lubrication, heat exchangers, microfluidics and hygiene products. These present opportunities for innovations, not only in product functionality, but also for fabrication processes, where resources and environmental impact can be reduced.

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“…[ 4 ] These biological inspired systems enable droplet motion via capillary phenomena, [10][11][12] mechanical vibrations, [ 13 ] chemical patterning, [14][15][16] and gradients of texture. [ 17,18 ] In addition, deterministically designed systems provide a robust, manufacturable platform that can even take advantage of unique scenarios not found in nature, such as the Leidenfrost effect [ 19 ] or reversible electrowetting.…”

Section: Doi: 101002/admi201400337mentioning

confidence: 99%

“…Controlling droplet motion is of signifi cant interest for a broad range of applications including microfl uidics, [ 1,2 ] water harvesting, [ 3,4 ] printing, [ 5 ] and chemical sensing. [ 6 ] The use of asymmetrically structured surfaces, commonly referred to as ratchets, has been widely investigated as a means to control multiphase fl uid fl ows, in particular droplet motion.…”

Section: Introductionmentioning

confidence: 99%

Length Scale Selects Directionality of Droplets on Vibrating Pillar Ratchet

Agapov

Boreyko

Briggs

et al. 2014

Adv Materials Inter

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Directional control of droplet motion at room temperature is of interest for applications such as microfluidic devices, self‐cleaning coatings, and directional adhesives. Here, arrays of tilted pillars ranging in height from the nanoscale to the microscale are used as structural ratchets to directionally transport water at room temperature. Water droplets deposited onto vibrating chips with a nanostructured ratchet move preferentially in the direction of the feature tilt while the opposite directionality is observed in the case of microstructured ratchets. This remarkable switch in directionality is consistent with changes in the contact angle hysteresis. To glean further insights into the length scale dependent asymmetric contact angle hysteresis, the contact lines formed by a nonvolatile room temperature ionic liquid placed onto the tilted pillar arrays were visualized and analyzed in situ in a scanning electron microscope. The ability to tune droplet directionality by merely changing the length scale of surface features all etched at the same tilt angle would be a versatile tool for manipulating multiphase flows and for selecting droplet directionality in other lap‐on‐chip applications.

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Water transport mechanism through open capillaries analyzed by direct surface modifications on biological surfaces

Cited by 46 publications

References 18 publications

Surfaces Inspired by the Nepenthes Peristome for Unidirectional Liquid Transport

Surfaces Inspired by the Nepenthes Peristome for Unidirectional Liquid Transport

Passive water collection with the integument: mechanisms and their biomimetic potential

Length Scale Selects Directionality of Droplets on Vibrating Pillar Ratchet

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