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首页> 外文期刊>ACS applied materials & interfaces >Tree Frog-Inspired Micropillar Arrays with Nanopits on the Surface for Enhanced Adhesion under Wet Conditions
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Tree Frog-Inspired Micropillar Arrays with Nanopits on the Surface for Enhanced Adhesion under Wet Conditions

机译:树蛙启发的微量微米阵列,表面上的纳米载体,用于在潮湿条件下提高粘附性

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摘要

Inspired by the nanoconcave top of epidermal cells on tree frogs' toe pads, an array of composite micropillars with nanopits on the surface (CPp) has been designed. Polystyrene (PS) nanoparticles are mixed with polydimethylsiloxane (PDMS) and serve as the template for nanopits on the PS/PDMS composite micropillars. CPp shows much larger wet adhesion compared to the arrays of micropillars without nanopits. Under a certain loading force, most of the liquid between CPp and the counterpart surface is squeezed out, so the liquid that remained in nanopits forms multiple nanoscale liquid bridges within the contact area of a single micropillar. Moreover, a large loading force could squeeze part of the liquid out of nanopits, resulting in the suction effect during the pull-off. The multiple liquid bridges, the suction effect, and the solid direct contact thus contribute to strong wet adhesion, which could be similar to 36.5 times that of tree frogs' toe pads. The results suggest the function of nanoconcaves on the toe pad of tree frogs and offer a new design strategy for structured adhesives to gain strong wet adhesion.
机译:灵感来自树脂脚趾垫上的表皮细胞的纳米能力顶部,设计了一系列具有纳米叶片的复合微粒(CPP)的复合微粒(CPP)。聚苯乙烯(PS)纳米颗粒与聚二甲基硅氧烷(PDMS)混合,并用作PS / PDMS复合微米上的纳米型纳米孔的模板。与没有纳米机器队三的微米阵列相比,CPP显示出更大的湿粘附。在一定的装载力下,CPP与对应表面之间的大部分液体被挤出,因此保持在纳米件中的液体在单微米的接触面积内形成多个纳米级液体桥。此外,大装载力可以挤出纳米机中的部分液体,导致在拉出期间的吸力效应。因此,多种液体桥,抽吸效果和固体直接接触有助于强烈的湿粘附,这可能类似于树蛙脚趾垫的36.5倍。结果表明了纳米凝固件在树蛙垫上的功能,为结构粘合剂提供了一种新的设计策略,以获得强烈的湿粘合。

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  • 来源
    《ACS applied materials & interfaces》 |2020年第16期|共7页
  • 作者

    Liu Quan; Meng Fandong; Wang Xin; Yang Baisong; Tan Di; Li Qian; Shi Zhekun; Shi Kui; Chen Wenhui; Liu Sheng; Lei Yifeng; Xue Longjian;

  • 作者单位

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

    Wuhan Univ Sch Power &

    Mech Engn Inst Technol Sci Wuhan 430072 Peoples R China;

  • 收录信息
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类 化学工业;
  • 关键词

    tree frog; wet adhesion; structured adhesion; bioinspired; porosity;

    机译:树蛙;湿粘附;结构粘附;生物悬浮;孔隙度;

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