A variational approach to moving contact line hydrodynamics

TIEZHENG QIAN; XIAO-PING WANG; PING SHENG

doi:10.1017/S0022112006001935

Abstract

In immiscible two-phase flows, the contact line denotes the intersection of the fluid–fluid interface with the solid wall. When one fluid displaces the other, the contact line moves along the wall. A classical problem in continuum hydrodynamics is the incompatibility between the moving contact line and the no-slip boundary condition, as the latter leads to a non-integrable singularity. The recently discovered generalized Navier boundary condition (GNBC) offers an alternative to the no-slip boundary condition which can resolve the moving contact line conundrum. We present a variational derivation of the GNBC through the principle of minimum energy dissipation (entropy production), as formulated by Onsager for small perturbations away from equilibrium. Through numerical implementation of a continuum hydrodynamic model, it is demonstrated that the GNBC can quantitatively reproduce the moving contact line slip velocity profiles obtained from molecular dynamics simulations. In particular, the transition from complete slip at the moving contact line to near-zero slip far away is shown to be governed by a power-law partial-slip regime, extending to mesoscopic length scales. The sharp (fluid–fluid) interface limit of the hydrodynamic model, together with some general implications of slip versus no slip, are discussed.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Lukyanov, A. V. and Shikhmurzaev, Y. D. 2007. Effect of flow field and geometry on the dynamic contact angle. Physical Review E, Vol. 75, Issue. 5,

2007. Capillary Flows with Forming Interfaces. p. 415.

SHENG, PING QIAN, TIEZHENG and WANG, XIAOPING 2007. HYDRODYNAMIC BOUNDARY CONDITION AT THE FLUID-SOLID INTERFACE. International Journal of Modern Physics B, Vol. 21, Issue. 23n24, p. 4131.

Ding, Hang and Spelt, Peter D. M. 2007. Wetting condition in diffuse interface simulations of contact line motion. Physical Review E, Vol. 75, Issue. 4,

He, Qiaolin and Wang, Xiao‐Ping 2008. The effect of the boundary slip on the stability of shear flow. ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik, Vol. 88, Issue. 9, p. 729.

Giacomelli, Lorenzo 2008. Non-linear higher-order boundary value problems describing thin viscous flows near edges. Journal of Mathematical Analysis and Applications, Vol. 345, Issue. 2, p. 632.

Sheng, Ping Qian, Tiezheng and Wang, Xiaoping 2008. Nanoscale Phenomena. Vol. 2, Issue. , p. 99.

QIAN, TIEZHENG QIU, CHUNYIN and SHENG, PING 2008. A scaling approach to the derivation of hydrodynamic boundary conditions. Journal of Fluid Mechanics, Vol. 611, Issue. , p. 333.

WANG, XIAO-PING QIAN, TIEZHENG and SHENG, PING 2008. Moving contact line on chemically patterned surfaces. Journal of Fluid Mechanics, Vol. 605, Issue. , p. 59.

Pooley, C. M. Kusumaatmaja, H. and Yeomans, J. M. 2008. Contact line dynamics in binary lattice Boltzmann simulations. Physical Review E, Vol. 78, Issue. 5,

Fang, Angbo Qian, Tiezheng and Sheng, Ping 2008. Generalized nematohydrodynamic boundary conditions with application to bistable twisted nematic liquid-crystal displays. Physical Review E, Vol. 78, Issue. 6,

Liang, Zhan-Peng Wang, Xiao-Dong Lee, Duu-Jong Peng, Xiao-Feng and Su, Ay 2009. Spreading dynamics of power-law fluid droplets. Journal of Physics: Condensed Matter, Vol. 21, Issue. 46, p. 464117.

Morfill, Gregor E. and Ivlev, Alexei V. 2009. Complex plasmas: An interdisciplinary research field. Reviews of Modern Physics, Vol. 81, Issue. 4, p. 1353.

Walker, Shawn W. Shapiro, Benjamin and Nochetto, Ricardo H. 2009. Electrowetting with contact line pinning: Computational modeling and comparisons with experiments. Physics of Fluids, Vol. 21, Issue. 10,

Xiong, Xiaomin Guo, Shuo Xu, Zuli Sheng, Ping and Tong, Penger 2009. Development of an atomic-force-microscope-based hanging-fiber rheometer for interfacial microrheology. Physical Review E, Vol. 80, Issue. 6,

Gao, Peng and Feng, James J. 2009. Enhanced slip on a patterned substrate due to depinning of contact line. Physics of Fluids, Vol. 21, Issue. 10,

Manservisi, S. and Scardovelli, R. 2009. A variational approach to the contact angle dynamics of spreading droplets. Computers & Fluids, Vol. 38, Issue. 2, p. 406.

Volkov, Oleg and Protas, Bartosz 2009. An inverse model for a free-boundary problem with a contact line: Steady case. Journal of Computational Physics, Vol. 228, Issue. 13, p. 4893.

Di, Yana and Wang, Xiao-Ping 2009. Precursor simulations in spreading using a multi-mesh adaptive finite element method. Journal of Computational Physics, Vol. 228, Issue. 5, p. 1380.

Bonn, Daniel Eggers, Jens Indekeu, Joseph Meunier, Jacques and Rolley, Etienne 2009. Wetting and spreading. Reviews of Modern Physics, Vol. 81, Issue. 2, p. 739.

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A variational approach to moving contact line hydrodynamics

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