通过结合壁虎和树蛙的粘附设计增强微柱阵列的粘附性。

Adhesion Enhancement of Micropillar Array by Combining the Adhesive Design from Gecko and Tree Frog.

机构信息

School of Power and Mechanical Engineering, The Institute of Technological Science, Wuhan University, South Donghu Road 8, Wuhan, 430072, China.

出版信息

Small. 2021 Jan;17(4):e2005493. doi: 10.1002/smll.202005493. Epub 2020 Dec 28.

DOI:10.1002/smll.202005493

PMID:33369100

Abstract

It has long been demonstrated the gecko-inspired micropillar array with T-shape tips possesses the best adhesion performance of a given material. The further enhancement of the adhesion performances of T-shape micropillars can offer redundant adhesion to compensate for the inevitable improper contacts. Here, the array of T-shape polydimethylsiloxane (PDMS) micropillars is incorporated with gradient dispersed calcium carbonate nanoparticles in the micropillar stalk, termed as T-shape gradient micropillars (TG), possessing the modulus gradient with stiff tip and soft root. The gradient modulus in TG facilitates the contact formation and regulates the stress at the detaching interface, resulting in a 4.6 times adhesion and 2.4 times friction as compared with the pure PDMS T-shape micropillar arrays. The study here provides a new design strategy for the super-strong structured dry adhesives.

摘要

具有 T 形尖端的仿壁虎微柱阵列早已被证明具有给定材料的最佳粘附性能。进一步增强 T 形微柱的粘附性能可以提供冗余的粘附力，以弥补不可避免的不当接触。在这里，聚二甲基硅氧烷 (PDMS) T 形微柱阵列与梯度分散的碳酸钙纳米颗粒在微柱茎中结合，称为 T 形梯度微柱 (TG)，具有从硬尖端到软根的模量梯度。TG 中的梯度模量有利于接触形成并调节脱离界面处的应力，从而使粘附力提高了 4.6 倍，摩擦力提高了 2.4 倍，与纯 PDMS T 形微柱阵列相比。本研究为超强结构型干式粘合剂提供了一种新的设计策略。

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通过结合壁虎和树蛙的粘附设计增强微柱阵列的粘附性。

Adhesion Enhancement of Micropillar Array by Combining the Adhesive Design from Gecko and Tree Frog.

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