Meeting the Contact-Mechanics Challenge

Martin H. Müser; Wolf B. Dapp; Romain Bugnicourt; Philippe Sainsot; Nicolas Lesaffre; Ton A. Lubrecht; Bo N.J. Persson; Kathryn Harris; Alexander Bennett; Kyle Schulze; Sean Rohde; Peter Ifju; W. Gregory Sawyer; Thomas Angelini; Hossein Ashtari Esfahani; Mahmoud Kadkhodaei; Saleh Akbarzadeh; Jiunn Jong Wu; Georg Vorlaufer; András Vernes; Soheil Solhjoo; Antonis I. Vakis; Robert L. Jackson; Yang Xu; Jeffrey Streator; Amir Rostami; Daniele Dini; Simon Medina; Giuseppe Carbone; Francesco Bottiglione; Luciano Afferrante; Joseph Monti; Lars Pastewka; Mark O. Robbins; James A. Greenwood

doi:10.1007/s11249-017-0900-2

Meeting the Contact-Mechanics Challenge

Martin H. Müser^*, Wolf B. Dapp, Romain Bugnicourt, Philippe Sainsot, Nicolas Lesaffre, Ton A. Lubrecht, Bo N.J. Persson, Kathryn Harris, Alexander Bennett, Kyle Schulze, Sean Rohde, Peter Ifju, W. Gregory Sawyer, Thomas Angelini, Hossein Ashtari Esfahani, Mahmoud Kadkhodaei, Saleh Akbarzadeh, Jiunn Jong Wu, Georg Vorlaufer, András VernesSoheil Solhjoo, Antonis I. Vakis, Robert L. Jackson, Yang Xu, Jeffrey Streator, Amir Rostami, Daniele Dini, Simon Medina, Giuseppe Carbone, Francesco Bottiglione, Luciano Afferrante, Joseph Monti, Lars Pastewka, Mark O. Robbins, James A. Greenwood

^*Corresponding author for this work

Department of Mechanical Engineering

Research output: Contribution to journal › Journal Article › peer-review

279 Scopus citations

Abstract

This paper summarizes the submissions to a recently announced contact-mechanics modeling challenge. The task was to solve a typical, albeit mathematically fully defined problem on the adhesion between nominally flat surfaces. The surface topography of the rough, rigid substrate, the elastic properties of the indenter, as well as the short-range adhesion between indenter and substrate, were specified so that diverse quantities of interest, e.g., the distribution of interfacial stresses at a given load or the mean gap as a function of load, could be computed and compared to a reference solution. Many different solution strategies were pursued, ranging from traditional asperity-based models via Persson theory and brute-force computational approaches, to real-laboratory experiments and all-atom molecular dynamics simulations of a model, in which the original assignment was scaled down to the atomistic scale. While each submission contained satisfying answers for at least a subset of the posed questions, efficiency, versatility, and accuracy differed between methods, the more precise methods being, in general, computationally more complex. The aim of this paper is to provide both theorists and experimentalists with benchmarks to decide which method is the most appropriate for a particular application and to gauge the errors associated with each one.

Original language	English
Article number	118
Journal	Tribology Letters
Volume	65
Issue number	4
DOIs	https://doi.org/10.1007/s11249-017-0900-2
State	Published - 01 12 2017

Bibliographical note

Publisher Copyright:
© 2017, Springer Science+Business Media, LLC.

Keywords

Adhesion
Contact mechanics
Modeling
Nominally flat surfaces

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10.1007/s11249-017-0900-2

Cite this

Müser, M. H., Dapp, W. B., Bugnicourt, R., Sainsot, P., Lesaffre, N., Lubrecht, T. A., Persson, B. N. J., Harris, K., Bennett, A., Schulze, K., Rohde, S., Ifju, P., Sawyer, W. G., Angelini, T., Ashtari Esfahani, H., Kadkhodaei, M., Akbarzadeh, S., Wu, J. J., Vorlaufer, G., ... Greenwood, J. A. (2017). Meeting the Contact-Mechanics Challenge. Tribology Letters, 65(4), Article 118. https://doi.org/10.1007/s11249-017-0900-2

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abstract = "This paper summarizes the submissions to a recently announced contact-mechanics modeling challenge. The task was to solve a typical, albeit mathematically fully defined problem on the adhesion between nominally flat surfaces. The surface topography of the rough, rigid substrate, the elastic properties of the indenter, as well as the short-range adhesion between indenter and substrate, were specified so that diverse quantities of interest, e.g., the distribution of interfacial stresses at a given load or the mean gap as a function of load, could be computed and compared to a reference solution. Many different solution strategies were pursued, ranging from traditional asperity-based models via Persson theory and brute-force computational approaches, to real-laboratory experiments and all-atom molecular dynamics simulations of a model, in which the original assignment was scaled down to the atomistic scale. While each submission contained satisfying answers for at least a subset of the posed questions, efficiency, versatility, and accuracy differed between methods, the more precise methods being, in general, computationally more complex. The aim of this paper is to provide both theorists and experimentalists with benchmarks to decide which method is the most appropriate for a particular application and to gauge the errors associated with each one.",

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Müser, MH, Dapp, WB, Bugnicourt, R, Sainsot, P, Lesaffre, N, Lubrecht, TA, Persson, BNJ, Harris, K, Bennett, A, Schulze, K, Rohde, S, Ifju, P, Sawyer, WG, Angelini, T, Ashtari Esfahani, H, Kadkhodaei, M, Akbarzadeh, S, Wu, JJ, Vorlaufer, G, Vernes, A, Solhjoo, S, Vakis, AI, Jackson, RL, Xu, Y, Streator, J, Rostami, A, Dini, D, Medina, S, Carbone, G, Bottiglione, F, Afferrante, L, Monti, J, Pastewka, L, Robbins, MO & Greenwood, JA 2017, 'Meeting the Contact-Mechanics Challenge', Tribology Letters, vol. 65, no. 4, 118. https://doi.org/10.1007/s11249-017-0900-2

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AU - Dapp, Wolf B.

AU - Bugnicourt, Romain

AU - Sainsot, Philippe

AU - Lesaffre, Nicolas

AU - Lubrecht, Ton A.

AU - Persson, Bo N.J.

AU - Harris, Kathryn

AU - Bennett, Alexander

AU - Schulze, Kyle

AU - Rohde, Sean

AU - Ifju, Peter

AU - Sawyer, W. Gregory

AU - Angelini, Thomas

AU - Ashtari Esfahani, Hossein

AU - Kadkhodaei, Mahmoud

AU - Akbarzadeh, Saleh

AU - Wu, Jiunn Jong

AU - Vorlaufer, Georg

AU - Vernes, András

AU - Solhjoo, Soheil

AU - Vakis, Antonis I.

AU - Jackson, Robert L.

AU - Xu, Yang

AU - Streator, Jeffrey

AU - Rostami, Amir

AU - Dini, Daniele

AU - Medina, Simon

AU - Carbone, Giuseppe

AU - Bottiglione, Francesco

AU - Afferrante, Luciano

AU - Monti, Joseph

AU - Pastewka, Lars

AU - Robbins, Mark O.

AU - Greenwood, James A.

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KW - Modeling

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DO - 10.1007/s11249-017-0900-2

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JO - Tribology Letters

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ER -

Meeting the Contact-Mechanics Challenge

Abstract

Bibliographical note

Keywords

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