Wetting Characteristics of Insect Wing Surfaces

Biological tiny structures have been observed on many kinds of surfaces such as lotus leaves, which have an effect on the coloration of Morpho butterflies and enhance the hydrophobicity of natural surfaces. We investigated the micro-scale and nano-scale structures on the wing surfaces of insects and...

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Veröffentlicht in:	Journal of Bionic Engineering 2009-03, Vol.6 (1), p.63-70
Hauptverfasser:	Byun, Doyoung, Hong, Jongin, Saputra, Ko, Jin Hwan, Lee, Young Jong, Park, Hoon Cheol, Byun, Bong-Kyu, Lukes, Jennifer R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal behavior Artificial Intelligence Biochemical Engineering Bioinformatics Biomaterials Biomedical Engineering and Bioengineering Biomedical Engineering/Biotechnology Cassie-Wenzel transition Engineering hierarchical structure insect wing Lotus micro- and nano-scale structures mimicry superhydrophobicity
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container_title	Journal of Bionic Engineering
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creator	Byun, Doyoung Hong, Jongin Saputra Ko, Jin Hwan Lee, Young Jong Park, Hoon Cheol Byun, Bong-Kyu Lukes, Jennifer R.
description	Biological tiny structures have been observed on many kinds of surfaces such as lotus leaves, which have an effect on the coloration of Morpho butterflies and enhance the hydrophobicity of natural surfaces. We investigated the micro-scale and nano-scale structures on the wing surfaces of insects and found that the hierarchical multiple roughness structures help in enhancing the hydrophobicity. After examining 10 orders and 24 species of flying Pterygotan insects, we found that micro-scale and nano-scale structures typically exist on both the upper and lower wing surfaces of flying insects. The tiny structures such as denticle or setae on the insect wings enhance the hydrophobicity, thereby enabling the wings to be cleaned more easily. And the hydrophobic insect wings undergo a transition from Cassie to Wenzel states at pitch/size ratio of about 20. In order to examine the wetting characteristics on a rough surface, a biomimetic surface with micro-scale pillars is fabricated on a silicon wafer, which exhibits the same behavior as the insect wing, with the Cassie-Wenzel transition occurring consistently around a pitch/width value of 20.
doi_str_mv	10.1016/S1672-6529(08)60092-X
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subjects	Animal behavior Artificial Intelligence Biochemical Engineering Bioinformatics Biomaterials Biomedical Engineering and Bioengineering Biomedical Engineering/Biotechnology Cassie-Wenzel transition Engineering hierarchical structure insect wing Lotus micro- and nano-scale structures mimicry superhydrophobicity
title	Wetting Characteristics of Insect Wing Surfaces
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