Adhesive contact mechanics of bio-inspired pillars: Exploring hysteresis and detachment modes

IF 3.2 3区 材料科学 Q2 ENGINEERING, CHEMICAL
G. Violano, S. Dibitonto, L. Afferrante
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Abstract

Engineering technologies frequently draw inspiration from nature, as exemplified in bio-inspired adhesive surfaces. These surfaces present textures adorned by pillars, mimicking the topography found on the pads of certain animals renowned for their exceptional adhesive capabilities. The adhesive response is strongly influenced by the morphology of these pillars. In typical existing models, perfect bonding conditions are assumed between the pillar and the countersurface, and solely the detachment process of the pillar from the countersurface is investigated.

The proposed model, based on the assumption that interactions at the interface are governed by van der Waals forces modeled by the Lennard-Jones potential law, enables the examination of the entire approach and retraction cycle, tracking the movement of the pillar towards and away from the countersurface.

Our findings reveal that adhesive contact mechanics is primarily influenced by the geometry of the pillar and the potential presence of interfacial ’defects’, which in turn affect the distribution of contact pressure. Furthermore, we show that the detachment process may simultaneously involve various modes of separation, such as crack propagation from outer edge, crack propagation from inner defects, and uniform decohesion. This suggests that existing theoretical models alone cannot fully elucidate the complexity of detachment phenomena. Additionally, we anticipate the occurrence of hysteretic losses during the approach-retraction cycle, attributed to pull-in and pull-off contact jumps. Adhesive hysteresis is a phenomenon consistently observed in experiments but frequently overlooked in existing models.

生物启发支柱的粘合接触力学:探索滞后和脱离模式
工程技术经常从大自然中汲取灵感,生物启发粘合剂表面就是一例。这些表面呈现出由支柱装饰的纹理,模仿了某些因其卓越的粘附能力而闻名的动物脚垫上的地形。这些支柱的形态对粘合反应有很大影响。在现有的典型模型中,柱子和反面之间的完美粘合条件是假定的,并且只研究了柱子从反面脱离的过程。我们提出的模型是基于界面上的相互作用受范德华力支配的假定,以伦纳德-琼斯势律为模型,能够检查整个接近和缩回周期,跟踪柱子向反面移动和脱离反面的过程。我们的研究结果表明,粘合接触力学主要受支柱的几何形状和可能存在的界面 "缺陷 "的影响,而界面 "缺陷 "又反过来影响接触压力的分布。此外,我们还发现分离过程可能同时涉及多种分离模式,例如从外缘开始的裂纹扩展、从内部缺陷开始的裂纹扩展以及均匀脱粘。这表明,仅凭现有的理论模型无法完全阐明分离现象的复杂性。此外,我们预计在接近-脱离周期中会出现滞后损失,这归因于拉入和拉出接触跳跃。粘滞是一种在实验中不断观察到的现象,但在现有模型中却经常被忽视。
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来源期刊
International Journal of Adhesion and Adhesives
International Journal of Adhesion and Adhesives 工程技术-材料科学:综合
CiteScore
6.90
自引率
8.80%
发文量
200
审稿时长
8.3 months
期刊介绍: The International Journal of Adhesion and Adhesives draws together the many aspects of the science and technology of adhesive materials, from fundamental research and development work to industrial applications. Subject areas covered include: interfacial interactions, surface chemistry, methods of testing, accumulation of test data on physical and mechanical properties, environmental effects, new adhesive materials, sealants, design of bonded joints, and manufacturing technology.
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