A Multi-Scale Contact Model for Rough Surfaces Under Loading and Unloading Conditions

Xuerui Zhang; Hongda Shen; Fuli Zhang; Guorui Zhang; Huanxiong Xia; Jianhua Liu; Xiaohui Ao; Juncheng Luo; Xuedong Zhu; Jian Zhang; Xiaohu Wu

doi:10.1007/s11249-025-02005-z

A Multi-Scale Contact Model for Rough Surfaces Under Loading and Unloading Conditions

Xuerui Zhang, Hongda Shen, Fuli Zhang, Guorui Zhang, Huanxiong Xia^*, Jianhua Liu, Xiaohui Ao, Juncheng Luo, Xuedong Zhu, Jian Zhang, Xiaohu Wu

^*Corresponding author for this work

School of Mechanical Engineering

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

1 Citation (Scopus)

Abstract

The contact of rough surfaces is a fundamental issue in analyzing friction, wear, and assembly of two parts. This study developed a multi-scale contact model for rough surfaces. Shoulder-shoulder elastoplastic contact, substrate deformation, and asperity interaction were considered in the asperity scale. A fractal representation was introduced to the contact model in the rough-surface scale, where the critical length scale and critical contact area were determined in the asperity scale. The proposed contact model was validated through comparisons with experimental data, simulation results, and other analytical models. Then, the effects of the surface topography, material properties, and largest length scale on rough-surface contact were examined, and the difference between the shoulder-shoulder and tip-tip contact modes was clarified.

Original language	English
Article number	70
Journal	Tribology Letters
Volume	73
Issue number	2
DOIs	http://doi.org/10.1007/s11249-025-02005-z
Publication status	Published - Jun 2025

Keywords

Asperity length scale
Contact mechanics
Fractal surface
Shoulder-shoulder contact

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10.1007/s11249-025-02005-z

Cite this

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title = "A Multi-Scale Contact Model for Rough Surfaces Under Loading and Unloading Conditions",

abstract = "The contact of rough surfaces is a fundamental issue in analyzing friction, wear, and assembly of two parts. This study developed a multi-scale contact model for rough surfaces. Shoulder-shoulder elastoplastic contact, substrate deformation, and asperity interaction were considered in the asperity scale. A fractal representation was introduced to the contact model in the rough-surface scale, where the critical length scale and critical contact area were determined in the asperity scale. The proposed contact model was validated through comparisons with experimental data, simulation results, and other analytical models. Then, the effects of the surface topography, material properties, and largest length scale on rough-surface contact were examined, and the difference between the shoulder-shoulder and tip-tip contact modes was clarified.",

keywords = "Asperity length scale, Contact mechanics, Fractal surface, Shoulder-shoulder contact",

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doi = "10.1007/s11249-025-02005-z",

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T1 - A Multi-Scale Contact Model for Rough Surfaces Under Loading and Unloading Conditions

AU - Zhang, Xuerui

AU - Shen, Hongda

AU - Zhang, Fuli

AU - Zhang, Guorui

AU - Xia, Huanxiong

AU - Liu, Jianhua

AU - Ao, Xiaohui

AU - Luo, Juncheng

AU - Zhu, Xuedong

AU - Zhang, Jian

AU - Wu, Xiaohu

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2025.

PY - 2025/6

Y1 - 2025/6

N2 - The contact of rough surfaces is a fundamental issue in analyzing friction, wear, and assembly of two parts. This study developed a multi-scale contact model for rough surfaces. Shoulder-shoulder elastoplastic contact, substrate deformation, and asperity interaction were considered in the asperity scale. A fractal representation was introduced to the contact model in the rough-surface scale, where the critical length scale and critical contact area were determined in the asperity scale. The proposed contact model was validated through comparisons with experimental data, simulation results, and other analytical models. Then, the effects of the surface topography, material properties, and largest length scale on rough-surface contact were examined, and the difference between the shoulder-shoulder and tip-tip contact modes was clarified.

AB - The contact of rough surfaces is a fundamental issue in analyzing friction, wear, and assembly of two parts. This study developed a multi-scale contact model for rough surfaces. Shoulder-shoulder elastoplastic contact, substrate deformation, and asperity interaction were considered in the asperity scale. A fractal representation was introduced to the contact model in the rough-surface scale, where the critical length scale and critical contact area were determined in the asperity scale. The proposed contact model was validated through comparisons with experimental data, simulation results, and other analytical models. Then, the effects of the surface topography, material properties, and largest length scale on rough-surface contact were examined, and the difference between the shoulder-shoulder and tip-tip contact modes was clarified.

KW - Asperity length scale

KW - Contact mechanics

KW - Fractal surface

KW - Shoulder-shoulder contact

UR - http://www.scopus.com/pages/publications/105004662894

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DO - 10.1007/s11249-025-02005-z

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SN - 1023-8883

VL - 73

JO - Tribology Letters

JF - Tribology Letters

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ER -

A Multi-Scale Contact Model for Rough Surfaces Under Loading and Unloading Conditions

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Keywords

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