Modelling droplet sliding angle on hydrophobic wire screens

Colloids and Surfaces A: Physicochemical and Engineering Aspects

Volumn 538, Issue , 2018, Pages 310-319

  Venkateshan, D G ^a   Tafreshi, H Vahedi ^a  

^a Virginia Commonwealth University   (United States)

Author keywords

Contact angle; Droplet; Hydrophobic screen; Sliding angle; Wetting

Indexed keywords

CONTACT ANGLE; HYDROPHOBICITY; MAGNETIC BUBBLES; NUMERICAL MODELS; PHASE INTERFACES; WETTING; WIRE;

FINITE ELEMENT SOLVER; QUANTITATIVE INFORMATION; SCREEN SYSTEMS; SLIDING ANGLE; SURFACE EVOLVER CODE; THREE-PHASE CONTACT LINE; WATER INTERFACE; WIRE DIAMETER;

DROPS;

ARTICLE; CONTACT ANGLE; GEOMETRY; HYDROPHOBICITY; MATHEMATICAL COMPUTING; PRIORITY JOURNAL; QUANTITATIVE STUDY; STRUCTURE ANALYSIS; SURFACE PROPERTY;

EID: 85033403602     PISSN: 09277757     EISSN: 18734359     Source Type: Journal    
DOI: 10.1016/j.colsurfa.2017.11.003     Document Type: Article

References (58)

1. Davis, A.M.J., Lauga, E., The friction of a mesh-like super-hydrophobic surface. Phys. Fluids, 21, 2009, 113101.
2. Srinivasan, S., Choi, W., Park, K.C., Chhatre, S.S., Cohen, R.E., McKinley, G.H., Drag reduction for viscous laminar flow on spray-coated non-wetting surfaces. Soft Matter 9 (2013), 5691–5702.
3. Brennan, J.C., Geraldi, N.R., Morris, R.H., Fairhurst, D.J., McHale, G., Newton, M.I., Flexible conformable hydrophobized surfaces for turbulent flow drag reduction. Sci. Rep., 5, 2015, 10267.
4. Srinivasan, S., Kleingartner, J.A., Gilbert, J.B., Cohen, R.E., Milne, A.J.B., McKinley, G.H., Sustainable drag reduction in turbulent Taylor-Couette flows by depositing sprayable superhydrophobic surfaces. Phys. Rev. Lett., 114, 2015, 014501.
5. Venkateshan, D.G., Amrei, M.M., Hemeda, A.A., Cullingsworth, Z., Corbett, J., Tafreshi, H.V., Failure pressures and drag reduction benefits of superhydrophobic wire screens. Colloids Surf. A, 511, 2016, 247.
6. Lee, C.H., Johnson, N., Drelich, J., Yap, Y.K., The performance of superhydrophobic and superoleophilic carbon nanotube meshes in water–oil filtration. Carbon 49 (2011), 669–676.
7. Song, J., Huang, S., Lu, Y., Bu, X., Mates, J.E., Ghosh, A., Ganguly, R., Carmalt, C.J., Parkin, I.P., Xu, W., Megaridis, C.M., Self-driven one-step oil removal from oil spill on water via selective-wettability steel mesh. ACS Appl. Mater. Interfaces 6 (2014), 19858–19865.
8. Li, J., Yan, L., Li, H., Li, J., Zha, F., Lei, Z., A facile one-step spray-coating process for the fabrication of a superhydrophobic attapulgite coated mesh for use in oil/water separation. RSC Adv., 5, 2015, 53802.
9. Darmanin, T., Tarrade, J., Celia, E., Guittard, F., Superoleophobic meshes with high adhesion by electrodeposition of conducting polymer containing short perfluorobutyl chains. J Phys. Chem. C 118 (2014), 2052–2057.
10. Grynyov, R., Bormashenko, Edward, Whyman, G., Bormashenko, Y., Musin, A., Pogreb, R., Starostin, A., Valtsifer, V., Strelnikov, V., Schechter, A., Kolagatla, S., Superoleophobic surfaces obtained via hierarchical metallic meshes. Langmuir 32 (2016), 4134–4140.
11. Fang, J., Aljuhani, A., Chase, G.G., Water drop movement on woven fiber mat surfaces due to flow of diesel Fuel. Sep. Purif. Technol. 171 (2016), 123–130.
12. Ganne, A., Lebed, V.O., Gavrilov, A.I., Combined wet chemical etching and anodic oxidation for obtaining the superhydrophobic meshes with anti-icing performance. Colloids Surf. A 499 (2016), 150–155.
13. Ling, E.J.Y., Uong, V., Renault-Crispo, J.-S., Kietzig, A.-M., Servio, P., Reducing ice adhesion on nonsmooth metallic surfaces: wettability and topography effects. ACS Appl. Mater. Interfaces 8 (2016), 8789–8800.
14. Geraldi, N.R., McHale, G., Xu, B.B., Wells, G.G., Dodd, L.E., Wood, D., Newton, M.I., Leidenfrost transition temperature for stainless steel meshes. Mater. Lett. 176 (2016), 205–208.
15. Chhatre, S.S., Choi, W., Tuteja, A., Park, K.-C., Mabry, J.M., McKinley, G.H., Cohen, R.E., Scale dependence of omniphobic mesh surfaces. Langmuir 26 (2010), 4027–4035.
16. Michielson, S., Lee, H.J., Design of a superhydrophobic surface using woven structures. Langmuir 23 (2007), 6004–6010.
17. Jiang, Z.X., Geng, L., Huang, Y.D., Guan, S.A., Dong, W., Ma, Z.Y., The model of rough wetting for hydrophobic steel meshes that mimic Asparagus setaceus leaf. J. Colloid Interface Sci. 354 (2011), 866–872.
18. Park, K.-C., Chhatre, S.S., Srinivasan, S., Cohen, R.E., McKinley, G.H., Optimal design of permeable fiber network structures for fog harvesting. Langmuir 29 (2013), 13269–13277.
19. Rajaram, M., Heng, X., Oza, M., Enhancement of fog-collection efficiency of a Raschel mesh using surface coatings and local geometric changes. Colloids Surf. A 508 (2016), 218–229.
20. Wu, J., Zhang, L., Wang, Y., Wang, P., Efficient and anisotropic fog harvesting on a hybrid and directional surface. Adv. Mater. Interfaces, 4, 2017, 1600801.
21. Shirtcliffe, N.J., McHale, G., Atherton, S., Newton, M.I., An introduction to superhydrophobicity. Adv. Colloid Interface Sci. 161 (2010), 124–138.
22. Rothstein, J.P., Slip on superhydrophobic surfaces. Annu Rev. Fluid Mech. 42 (2010), 89–109.
23. Lee, C., Choi, C.-H., Kim, C.-J., Structured surfaces for giant liquid slip. Phys. Rev. Lett., 101, 2008, 064501.
24. Hemeda, A., Tafreshi, H.V., Instantaneous slip-length in superhydrophobic microchannels: grooves with dissimilar walls or arbitrary wall curvatures. Phys. Fluids, 27, 2015, 102101.
25. Quere, D., Drops at rest on a tilted plane. Langmuir 14 (1998), 2213–2216.
26. Yoshimitsu, Z., Nakajima, A., Watanabe, T., Hashimoto, K., Effects of surface structure on the hydrophobicity and sliding behavior of water droplets. Langmuir 18 (2002), 5818–5822.
27. Extrand, C.W., Designing for optimum liquid repellency. Langmuir, 22, 2006, 1711.
28. ElSherbini a, A.I., Jacobi, A.M., Retention forces and CAs for critical liquid drops on non-horizontal surfaces. J. Colloid Interface Sci. 299 (2006), 841–849.
29. Yadav, P.S., Bahadur, P., Tadmor, R., Chaurasia, K., Leh, A., Drop retention force as a function of drop size. Langmuir 24 (2008), 3181–3184.
30. Balu, B., Berry, A.D., Hess, D.W., Breedveld, V., Patterning of superhydrophobic paper to control the mobility of micro-liter drops for two-dimensional lab-on-paper applications. Lab Chip 9 (2009), 3066–3075.
31. Lv, Cunjing, Yang, Changwei, Hao, Pengfei, He, Feng, Zheng, Quanshui, Sliding of water droplets on microstructured hydrophobic surfaces. Langmuir 26:11 (2010), 8704–8708.
32. Extrand, C.W., Moon, Sung, Repellency of the lotus leaf: CAs, drop retention, and sliding angles. Langmuir 30 (2014), 8791–8797.
33. Yang, X., Liu, X., Lu, Y., Zhou, S., Gao, M., Song, J., Xu, W., Controlling the adhesion of superhydrophobic surfaces using electrolyte jet machining techniques. Sci. Rep., 6, 2016, 23985.
34. Choi, H., Liang, H., Wettability and spontaneous penetration of a water drop into hydrophobic pores. J. Colloid Interface Sci. 477 (2016), 176–180.
35. Amrei, M.M., Venkateshan, D.G., D'Souza, N., Atulasimha, J., Tafreshi, H.V., Novel approach to measuring the droplet detachment force from fibers. Langmuir, 32, 2016, 13333.
36. Amrei, M.M., Davoudi, M., Chase, G.G., Tafreshi, H.V., Effects of roughness on droplet apparent CAs on a fiber. Sep Purif. Technol., 180, 2017, 107.
37. Marmur, A., Wetting on hydrophobic rough surfaces: to be heterogeneous or not to be?. Langmuir, 19, 2003, 8343.
38. Marmur, A., The lotus effect: superhydrophobicity and metastability. Langmuir 20 (2004), 3517–3519.
39. Extrand, C.W., Model for contact angles and hysteresis on rough and ultraphobic surfaces. Langmuir 18 (2002), 7991–7999.
40. Chhatre, S.S., Tuteja, A., Choi, W., Revaux, A., Smith, D., Mabry, J.M., McKinley, G.H., Cohen, R.E., Thermal annealing treatment to achieve switchable and reversible oleophobicity on fabrics. Langmuir 25 (2009), 13625–13632.
41. Kleingartner, J.A., Srinivasan, S., Truong, Q.T., Sieber, M., Cohen, R.E., McKinley, G.H., Designing robust hierarchically textured oleophobic fabrics. Langmuir 31 (2015), 13201–13213.
42. Feng, L., Zhang, Z., Mai, Z., Ma, Y., Liu, B., Jiang, L., Zhu, D., A super-Hydrophobic and super-oleophilic coating mesh film for the separation of oil and water. Angew. Chem. Int. Ed. 43 (2004), 2012–2014.
43. Milne, A.J.B., Amirfazli, A., The Cassie equation: how it is meant to be used. Adv. Colloid Interface Sci. 170 (2012), 48–55.
44. Kawasaki, K., Study of wettability of polymers by sliding of water drop. J. Colloid Sci. 15:5 (1960), 402–407.
45. Krasovitski, B., Marmur, A., Drops down the hill: theoretical study of limiting contact angles and the hysteresis range on a tilted plate. Langmuir 21 (2005), 3881–3885.
46. Chou, T.H., Hong, S.J., Sheng, Y.J., Tsao, H.K., Drops sitting on a tilted plate: receding and advancing pinning. Langmuir 28 (2012), 5158–5166.
47. Aziz, H., Amrei, M.M., Dotivala, A., Tang, C., Tafreshi, H.V., Modeling cassie droplets on superhydrophobic coatings with orthogonal fibrous structures. Colloids Surf. A, 512, 2017, 61.
48. Brandon, S., Haimovich, N., Yeger, E., Marmur, A., Partial wetting of chemically patterned surfaces: the effect of drop size. J. Colloid Interface Sci. 263 (2003), 237–243.
49. Marmur, A., Soft contact: measurement and interpretation of contact angles. Soft Matter 2 (2006), 12–17.
50. Marmur, A., Bittoun, E., When wenzel and cassie are right: reconciling local and global considerations. Langmuir, 25(3), 2009, 1279.
51. Milionis, A., Fragouli, D., Martiradonna, L., Anyfantis, G.C., Cozzoli, P.D., Bayer, I.S., Athanassiou, A., Spatially controlled surface energy traps on superhydrophobic surfaces. ACS Appl Mater. Interfaces 6 (2014), 1036–1043.
52. Zhang, R., Hao, P., He, F., Drop impact on oblique superhydrophobic surfaces with two-tier roughness. Langmuir 33 (2017), 3556–3567.
53. Zhang, B., Wang, J., Zhang, X., Effects of the hierarchical structure of rough solid surfaces on the wetting of microdroplets. Langmuir 29 (2013), 6652–6658.
54. Adam, T.P., Varanasi, K.K., Self-similarity of contact line depinning from textured surfaces. Nat. Commun., 4, 2013, 1492.
55. Dussan V, E.B., Chow, R.T.-P., On the ability of drops or bubbles to stick to nonhorizontal surfaces of solids. J. Fluid Mech. 137 (1983), 1–29.
56. Schellenberger, F., Encinas, N., Vollmer, D., Butt, H.J., How water advances on superhydrophobic surfaces. Phys. Rev. Lett., 116, 2016, 096101.
57. Extrand, C.W., Repellency of the lotus leaf: resistance to water intrusion under hydrostatic pressure. Langmuir 27 (2011), 6920–6925.
58. Yoshimitsu, Z., Nakajima, A., Watanabe, T., Hashimoto, K., Effects of surface structure on the hydrophobicity and sliding behavior of water droplets. Langmuir 18 (2002), 5818–5822.