Effect of Surface Grooves on the Static Friction of an Elastic Slider

Capozza, Rosario; Pugno, Nicola

doi:10.1007/s11249-015-0510-9

Cited by 22 publications

(24 citation statements)

References 26 publications

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“…We start with a periodic regular succession of grooves and pawls. This pattern has already been studied both experimentally [20,21] and numerically with a slightly different model [34]. Our aim is therefore to first obtain known results so as to validate the model.…”

Section: A First-level Patterningmentioning

confidence: 91%

“…This model was first introduced by Burridge and Knopoff [22] in the study of the elastic deformation of tectonic plates. Despite its simplicity, the model is still used not only in this field [23][24][25], but also to investigate some aspects of dry friction on elastic surfaces, e.g., the static to dynamic friction transition [26][27][28][29][30], stick-slip behavior [31][32][33], and the role of regular patterning [34].…”

Section: Modelmentioning

confidence: 99%

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Static and dynamic friction of hierarchical surfaces

2016

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Hierarchical structures are very common in nature, but only recently have they been systematically studied in materials science, in order to understand the specific effects they can have on the mechanical properties of various systems. Structural hierarchy provides a way to tune and optimize macroscopic mechanical properties starting from simple base constituents and new materials are nowadays designed exploiting this possibility. This can be true also in the field of tribology. In this paper we study the effect of hierarchical patterned surfaces on the static and dynamic friction coefficients of an elastic material. Our results are obtained by means of numerical simulations using a one-dimensional spring-block model, which has previously been used to investigate various aspects of friction. Despite the simplicity of the model, we highlight some possible mechanisms that explain how hierarchical structures can significantly modify the friction coefficients of a material, providing a means to achieve tunability.

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Section: A First-level Patterningmentioning

confidence: 91%

Section: Modelmentioning

confidence: 99%

Static and dynamic friction of hierarchical surfaces

2016

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“…One of the most widely used models is the one dimensional spring-block model, which was originally introduced to study earthquakes [29]- [31] and has also been used to investigate many aspects of dry friction of elastic materials [32]- [39]. In [40] we have extensively investigated the general behavior of the model and the effects of local patterning (regular and hierarchical) on the macroscopic friction coefficients, and in [41] we have extended the study to composite surfaces, i.e.…”

Section: Introductionmentioning

confidence: 99%

A 2-D model for friction of complex anisotropic surfaces

Costagliola

Bosia

Pugno

2018

Journal of the Mechanics and Physics of Solids

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The friction force observed at macroscale is the result of interactions at various lower length scales that are difficult to model in a combined manner. For this reason, simplified approaches are required, depending on the specific aspect to be investigated. In particular, the dimensionality of the system is often reduced, especially in models designed to provide a qualitative description of frictional properties of elastic materials, e.g. the spring-block model. In this paper, we implement for the first time a two dimensional extension of the spring-block model, applying it to structured surfaces and investigating by means of numerical simulations the frictional behaviour of a surface in the presence of features like cavities, pillars or complex anisotropic structures. We show how friction can be effectively tuned by appropriate design of such surface features.

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“…The structure considered in figure 3 is similar to a patterned surface with grooves, in which the friction coefficient is assumed to be zero. In this case, it is known both from numerical studies [7] and experimental results [41][42] that static friction decreases with the width of the grooves. In our previous work [10] we have also shown that this is due to the increase of the shear stress concentrations at the edge of the grooves.…”

Section: Friction On Variable-roughness Patterned Surfacesmentioning

confidence: 99%

“…grooves and pawls perpendicular to the direction of motion. The effects of these structures have been studied both numerically [7] and experimentally [8] [9], and recently their hierarchical arrangement has also been investigated by means of numerical simulations [10]: results show that by changing the architecture of the contact surface only, the global static friction coefficients can be tuned without changing the chemical or physical properties of the material. This is because by exploiting patterning it is possible to modify mesoscopic features, i.e.…”

Section: Introductionmentioning

confidence: 99%

Tuning friction with composite hierarchical surfaces

Costagliola

Bosia

Pugno

2017

Tribology International

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Macroscopic friction coefficients observed in experiments are the result of various types of complex multiscale interactions between sliding surfaces. Therefore, there are several ways to modify them depending on the physical phenomena involved. Recently, it has been demonstrated that surface structure, e.g. artificial patterning, can be used to tune frictional properties. In this paper, we show how the global friction coefficients can also be manipulated using composite surfaces with varying roughness or stiffness values, i.e. by combining geometrical features with the modification of local friction coefficients or stiffnesses. We show that a remarkable reduction of static friction can be achieved by introducing hierarchical arrangements of varying local roughness values, or by introducing controlled material stiffness variations.Comment: 16 pages, 8 figure

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Effect of Surface Grooves on the Static Friction of an Elastic Slider

Cited by 22 publications

References 26 publications

Static and dynamic friction of hierarchical surfaces

Static and dynamic friction of hierarchical surfaces

A 2-D model for friction of complex anisotropic surfaces

Tuning friction with composite hierarchical surfaces

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