结合多角形结构和三相复合界面的蜜蜂花冠湿粘附研究进展

IF 6.3 1区 工程技术 Q1 ENGINEERING, MECHANICAL
Friction Pub Date : 2023-11-29 DOI:10.1007/s40544-023-0743-0
Lulu Liang, Jieliang Zhao, Qun Niu, Li Yu, Xiangbing Wu, Wenzhong Wang, Shaoze Yan, Zhenglei Yu
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引用次数: 0

摘要

受自然界动态湿式粘接系统的启发,各种人工粘接表面得到了发展,但仍面临着不同的挑战。至关重要的是,湿胶粘剂的理论力学从未得到充分的揭示。在此,我们开发了一种控制湿粘附的新型粘附机制,并研究了蜜蜂花叶再生天然湿粘附系统的生物学模型。利用低温扫描电镜(Cryo-SEM)观察了蜜蜂花蕊和花蕊版画的微纳结构,在接触界面上发现了明显的气穴。随后,形成具有三相复合界面(包括气穴、液体分泌和花蜜六边形框架)的黏附模型,分析蜜蜂花蜜的湿黏附。理论计算和实验结果表明,液体自吸效应和空气栓塞效应增强了蜜蜂的粘附机制。在这些作用下,可以通过控制接触区液体分泌和气穴的比例来调节正常粘附和剪切粘附。值得注意的是,空气栓塞效应有助于较小的正常粘附与较大的剪切粘附的最佳耦合,这有利于蜜蜂的高跨步频率。这些工作可以为仿生湿粘接表面的发展提供一个新的视角。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Development of wet adhesion of honeybee arolium incorporated polygonal structure with three-phase composite interfaces

Development of wet adhesion of honeybee arolium incorporated polygonal structure with three-phase composite interfaces

Inspired by the dynamic wet adhesive systems in nature, various artificial adhesive surfaces have been developed but still face different challenges. Crucially, the theoretical mechanics of wet adhesives has never been sufficiently revealed. Here, we develop a novel adhesive mechanism for governing wet adhesion and investigate the biological models of honeybee arolium for reproducing the natural wet adhesive systems. Micro-nano structures of honeybee arolium and arolium-prints were observed by Cryogenic scanning electron microscopy (Cryo-SEM), and the air pockets were found in the contact interface notably. Subsequently, the adhesive models with a three-phase composite interface (including air pockets, liquid secretion, and hexagonal frames of arolium), were formed to analyze the wet adhesion of honeybee arolium. The results of theoretical calculations and experiments indicated an enhanced adhesive mechanism of the honeybee by liquid self-sucking effects and air-embolism effects. Under these effects, normal and shear adhesion can be adjusted by controlling the proportion of liquid secretion and air pockets in the contact zone. Notably, the air-embolism effects contribute to the optimal coupling of smaller normal adhesion with greater shear adhesion, which is beneficial for the high stride frequency of honeybees. These works can provide a fresh perspective on the development of bio-inspired wet adhesive surfaces.

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来源期刊
Friction
Friction Engineering-Mechanical Engineering
CiteScore
12.90
自引率
13.20%
发文量
324
审稿时长
13 weeks
期刊介绍: Friction is a peer-reviewed international journal for the publication of theoretical and experimental research works related to the friction, lubrication and wear. Original, high quality research papers and review articles on all aspects of tribology are welcome, including, but are not limited to, a variety of topics, such as: Friction: Origin of friction, Friction theories, New phenomena of friction, Nano-friction, Ultra-low friction, Molecular friction, Ultra-high friction, Friction at high speed, Friction at high temperature or low temperature, Friction at solid/liquid interfaces, Bio-friction, Adhesion, etc. Lubrication: Superlubricity, Green lubricants, Nano-lubrication, Boundary lubrication, Thin film lubrication, Elastohydrodynamic lubrication, Mixed lubrication, New lubricants, New additives, Gas lubrication, Solid lubrication, etc. Wear: Wear materials, Wear mechanism, Wear models, Wear in severe conditions, Wear measurement, Wear monitoring, etc. Surface Engineering: Surface texturing, Molecular films, Surface coatings, Surface modification, Bionic surfaces, etc. Basic Sciences: Tribology system, Principles of tribology, Thermodynamics of tribo-systems, Micro-fluidics, Thermal stability of tribo-systems, etc. Friction is an open access journal. It is published quarterly by Tsinghua University Press and Springer, and sponsored by the State Key Laboratory of Tribology (TsinghuaUniversity) and the Tribology Institute of Chinese Mechanical Engineering Society.
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