10.22190/FUME201221005P

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We consider a classical problem of a capillary neck between a parabolic body and a plane with a small amount of liquid in between. In the state of thermodynamic equilibrium, the contact area between the bodies and the liquid layer has a circular shape. However, if the bodies are forced to slowly move in the tangential direction, the shape will change due to the hysteresis of the contact angle. We discuss the form of the contact area under two limiting assumptions about the friction law in the boundary line. We also present a detailed experimental study of the shape of sliding capillary contact in dependence on the roughness of the contacting surfaces.

Capillarity, Contact Angle Hysteresis, Friction, Contact Area, Roughness

Bowden, F. P., Tabor, D., 2001, The Friction and Lubrication of Solids, Clarendon Press.

Popova, E., Popov, V.L., 2015, The research works of Coulomb and Amontons and generalized laws of friction, Friction, 3(2), pp. 183-190.

Persson, B.N.J., 2002, Sliding Friction. Physical Principles and Applications, Springer.

Popov, V.L., 2017, Contact Mechanics and Friction. Physical Principles and Applications, 2nd Edition, Berlin: Springer.

Semprebon, C., McHaleb, G., Kusumaatmaja, H., 2017, Apparent contact angle and contact angle hysteresis on liquid infused surfaces, Soft Matter, 13(1), pp. 101-110.

Gao, L., McCarthy, T.J., 2006, Contact angle hysteresis explained, Langmuir, 22, pp. 6234-6237.

Junchao, W., Wu, Y., Cao, Y., Li, G., Liao, Y., 2020, Influence of surface roughness on contact angle hysteresis and spreading work, Colloid and Polymer Science, 298, pp. 1107-1112.

Shia, Z., Zhang, Y., Liu, M., Hanaor, D.A.H., Gan, Y., 2018, Dynamic contact angle hysteresis in liquid bridges, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 555, pp. 365-371.

Heib, F., Schmitt, M., 2016, Statistical contact angle analyses with the high-precision drop shape analysis (HPDSA) approach: basic principles and applications, Coatings, 6(4), 57.

Wu, C.-J., Li, Y.-F., Woon, W.-Y., Sheng, Y.-J., Tsao, H.-K., 2016, Contact angle hysteresis on graphene surfaces and hysteresis-free behavior on oil-infused graphite surfaces, Applied Surface Science, 385, pp. 153-161.

Hubbe, M.A., Gardner, D.J., Shen, W., 2015, Contact angles and wettability of cellulosic surfaces: A review of proposed mechanisms and test strategies, BioResources, 10(4), pp. 8657-8749.

Popov, V.L., 2020, Shape of a sliding capillary contact, arXiv:2012.13979, http://arxiv.org/abs/2012.13979

Popov, V.L., Adhesion hysteresis due to chemical heterogeneity. In: Multiscale Biomechanics and Tribology of Inorganic and Organic Systems, Eds. Ostermeyer, Popov, Shilko, Vasiljeva, Springer, 2021, pp. 473-483.

Lyashenko, I.A., Pohrt, R., 2020, Adhesion between rigid indenter and soft rubber layer: Influence of roughness, Frontiers in Mechanical Engineering. Section Tribology, 6, 49.

Lyashenko, I.A., Popov, V.L., 2020, The effect of contact duration and indentation depth on adhesion strength: experiment and numerical simulation, Technical Physics, 65(10), pp. 1695-1707.

Popov, V.L., Lyashenko, I.A., Starcevic, J., 2021, Shape of a sliding capillary contact due to hysteresis of contact angle (experiment with indenter R=33mm), supplementary video. https://doi.org/10.13140/RG.2.2.13032.49923

Popov, V.L., Lyashenko, I.A., Starcevic, J., 2021, Shape of a sliding capillary contact due to hysteresis of contact angle (experiment with indenter R=100mm), supplementary video. https://doi.org/10.13140/RG.2.2.33165.15840