Why Static Friction Decreases From Single to Multi-asperity Contacts

Liang Peng, Thibault Roch, Daniel Bonn, Bart Weber
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Abstract

The key parameter for describing frictional strength at the onset of sliding is the static friction coefficient. Yet, how the static friction coefficient at the macroscale emerges from contacting asperities at the microscale is still an open problem. Here, we present friction experiments in which the normal load was varied over more than three orders of magnitude, so that a transition from a single asperity contact at low loads to multi-asperity contacts at high loads was achieved. We find a remarkable drop in static friction coefficient with increasing normal load. Using a simple stick-slip transition model we identify the presence of pre-sliding and subcritical contact points as the cause of smaller static friction coefficient at increased normal loads. Our measurements and model bridge the gap between friction behavior commonly observed in atomic force microscopy (AFM) experiments at microscopic forces, and industrially relevant multi-asperity contact interfaces loaded with macroscopic forces.
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为什么静摩擦力会从单个触头减少到多个触头
描述滑动开始时摩擦强度的关键参数是静摩擦系数。然而,宏观上的静摩擦系数是如何从微观上的接触表面产生的,这仍然是一个悬而未决的问题。在这里,我们展示了摩擦实验,在实验中,法向载荷的变化超过了三个数量级,从而实现了从低载荷时的单表面接触到高载荷时的多表面接触的过渡。我们发现,在法向载荷不断增加的情况下,静摩擦系数明显下降。利用一个简单的粘滑过渡模型,我们确定了预滑动和亚临界接触点的存在是法向载荷增加时静摩擦系数变小的原因。我们的测量结果和模型弥补了原子力显微镜(AFM)实验中通常观察到的微观力下的摩擦行为与工业上加载宏观力的多表面接触界面之间的差距。
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