TY - JOUR
T1 - Slipping moving contact lines
T2 - Critical roles of de Gennes's 'foot' in dynamic wetting
AU - Wei, Hsien Hung
AU - Tsao, Heng Kwong
AU - Chu, Kang Ching
N1 - Publisher Copyright:
© 2019 Cambridge University Press.
PY - 2019/8/25
Y1 - 2019/8/25
N2 - In the context of dynamic wetting, wall slip is often treated as a microscopic effect for removing viscous stress singularity at a moving contact line. In most drop spreading experiments, however, a considerable amount of slip may occur due to the use of polymer liquids such as silicone oils, which may cause significant deviations from the classical Tanner-de Gennes theory. Here we show that many classical results for complete wetting fluids may no longer hold due to wall slip, depending crucially on the extent of de Gennes's slipping 'foot' to the relevant length scales at both the macroscopic and microscopic levels. At the macroscopic level, we find that for given liquid height and slip length , the apparent dynamic contact angle can change from Tanner's law for to the strong-slip law for , where is the capillary number and is the macroscopic length scale. Such a no-slip-to-slip transition occurs at the critical capillary number , accompanied by the switch of the 'foot' of size from the inner scale to the outer scale with respect to . A more generalized dynamic contact angle relationship is also derived, capable of unifying Tanner's law and the strong-slip law under . We not only confirm the two distinct wetting laws using many-body dissipative particle dynamics simulations, but also provide a rational account for anomalous departures from Tanner's law seen in experiments (Chen, J. Colloid Interface Sci., vol. 122, 1988, pp. 60-72; Albrecht et al., Phys. Rev. Lett., vol. 68, 1992, pp. 3192-3195). We also show that even for a common spreading drop with small macroscopic slip, slip effects can still be microscopically strong enough to change the microstructure of the contact line. The structure is identified to consist of a strongly slipping precursor film of length followed by a mesoscopic 'foot' of width ahead of the macroscopic wedge, where is the molecular length. It thus turns out that it is the 'foot', rather than the film, contributing to the microscopic length in Tanner's law, in accordance with the experimental data reported by Kavehpour et al. (Phys. Rev. Lett., vol. 91, 2003, 196104) and Ueno et al. (Trans. ASME J. Heat Transfer, vol. 134, 2012, 051008). The advancement of the microscopic contact line is still led by the film whose length can grow as the power of time due to , as supported by the experiments of Ueno et al. and Mate (Langmuir, vol. 28, 2012, pp. 16821-16827). The present work demonstrates that the behaviour of a moving contact line can be strongly influenced by wall slip. Such slip-mediated dynamic wetting might also provide an alternative means for probing slippery surfaces.
AB - In the context of dynamic wetting, wall slip is often treated as a microscopic effect for removing viscous stress singularity at a moving contact line. In most drop spreading experiments, however, a considerable amount of slip may occur due to the use of polymer liquids such as silicone oils, which may cause significant deviations from the classical Tanner-de Gennes theory. Here we show that many classical results for complete wetting fluids may no longer hold due to wall slip, depending crucially on the extent of de Gennes's slipping 'foot' to the relevant length scales at both the macroscopic and microscopic levels. At the macroscopic level, we find that for given liquid height and slip length , the apparent dynamic contact angle can change from Tanner's law for to the strong-slip law for , where is the capillary number and is the macroscopic length scale. Such a no-slip-to-slip transition occurs at the critical capillary number , accompanied by the switch of the 'foot' of size from the inner scale to the outer scale with respect to . A more generalized dynamic contact angle relationship is also derived, capable of unifying Tanner's law and the strong-slip law under . We not only confirm the two distinct wetting laws using many-body dissipative particle dynamics simulations, but also provide a rational account for anomalous departures from Tanner's law seen in experiments (Chen, J. Colloid Interface Sci., vol. 122, 1988, pp. 60-72; Albrecht et al., Phys. Rev. Lett., vol. 68, 1992, pp. 3192-3195). We also show that even for a common spreading drop with small macroscopic slip, slip effects can still be microscopically strong enough to change the microstructure of the contact line. The structure is identified to consist of a strongly slipping precursor film of length followed by a mesoscopic 'foot' of width ahead of the macroscopic wedge, where is the molecular length. It thus turns out that it is the 'foot', rather than the film, contributing to the microscopic length in Tanner's law, in accordance with the experimental data reported by Kavehpour et al. (Phys. Rev. Lett., vol. 91, 2003, 196104) and Ueno et al. (Trans. ASME J. Heat Transfer, vol. 134, 2012, 051008). The advancement of the microscopic contact line is still led by the film whose length can grow as the power of time due to , as supported by the experiments of Ueno et al. and Mate (Langmuir, vol. 28, 2012, pp. 16821-16827). The present work demonstrates that the behaviour of a moving contact line can be strongly influenced by wall slip. Such slip-mediated dynamic wetting might also provide an alternative means for probing slippery surfaces.
KW - capillary flows
KW - contact lines
UR - http://www.scopus.com/inward/record.url?scp=85067601945&partnerID=8YFLogxK
U2 - 10.1017/jfm.2019.352
DO - 10.1017/jfm.2019.352
M3 - 期刊論文
AN - SCOPUS:85067601945
SN - 0022-1120
VL - 873
SP - 110
EP - 150
JO - Journal of Fluid Mechanics
JF - Journal of Fluid Mechanics
ER -