2015
DOI: 10.1038/am.2015.74
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Combining the lotus leaf effect with artificial photosynthesis: regeneration of underwater superhydrophobicity of hierarchical ZnO/Si surfaces by solar water splitting

Abstract: Fabrication of stable superhydrophobic surfaces in dynamic circumstances is a key issue for practical uses of non-wetting surfaces. However, superhydrophobic surfaces have finite lifetime in underwater conditions due to the diffusion of gas pockets into the water. To overcome this limited lifetime of underwater superhydrophobicity, this study introduces a novel method for regenerating a continuous air interlayer on superhydrophobic ZnO nanorod/Si micropost hierarchical structures (HRs) via the combination of t… Show more

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Cited by 55 publications
(40 citation statements)
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“…In this study we have developed new SiC/Si interlocked hierarchical structures using a carbothermal reduction based synthesis method 55 . Compared to previously reported structures, our surface drastically improved the lifetime of the air interlayer and showed the highest stability of underwater superhydrophobicity due to its unique networking structure 47 56 . According to our drag reduction measurements, our superhydrophobic SiC/Si hierarchical surface showed 56% drag reduction effect compared to a flat Si surface.…”
mentioning
confidence: 83%
“…In this study we have developed new SiC/Si interlocked hierarchical structures using a carbothermal reduction based synthesis method 55 . Compared to previously reported structures, our surface drastically improved the lifetime of the air interlayer and showed the highest stability of underwater superhydrophobicity due to its unique networking structure 47 56 . According to our drag reduction measurements, our superhydrophobic SiC/Si hierarchical surface showed 56% drag reduction effect compared to a flat Si surface.…”
mentioning
confidence: 83%
“…This semi-active method was proven effective under near-realistic conditions, such as a very high liquid pressure (up to 7 atm) and a defective surface. Lee and Yong (2015) also adopted a similar hierarchically structured surface to regenerate a gas layer on SHPo surface. But, they used solar energy instead of electrical energy to initiate the electrochemical gas generation.…”
Section: Toward Robust Plastron: Active Approachmentioning
confidence: 99%
“…The design approach to help keeping the plastron on a SHPo surface includes making the surface resistant to a wetting transition (Carlborg et al 2008;Lee and Kim 2009;Barthlott et al 2010;Carlborg and van der Wijngaart 2011) and adding a built-in mechanism that replenishes the gas on the surface on demand Kim 2011b, 2012;Lee and Yong 2015). The approach can be categorized depending on whether or not external energy is used, i.e., passive versus active approach, as summarized in Fig.…”
Section: Frailty Of Plastron On Large-slip Shpo Surfacesmentioning
confidence: 99%
“…We expect that this study will deepen the understanding of the physical mechanisms of superhydrophobicity and open up new possibilities for the design of functional surfaces and bioinspired materials. [27][28][29][30][31] …”
Section: Resultsmentioning
confidence: 99%