Ping Wei, Shoufa Wang, Yiming Wang, and Wenrong Yan
[1] D. Seveno, T.D. Blake, and J. De Coninck, Young’s equation atthe nanoscale, Physical Review Letters, 111(9), 2013, 096101. [2] B. Hou, C. Wu, X. Li, J. Huang, and M. Chen, Contactline-based model for the Cassie-Wenzel transition of a sessiledroplet on the hydrophobic micropillar-structured surfaces,Applied Surface Science, 542, 2021, 148611. [3] J. Zhang and Z. Kang, Effect of different liquid–solid contactmodels on the corrosion resistance of superhydrophobicmagnesium surfaces, Corrosion Science, 87, 2014, 452–459. [4] N. Verplanck, Y. Coffinier, V. Thomy, and R. Boukherroub,Wettability switching techniques on superhydrophobic surfaces,Nanoscale Research Letters, 2(12), 2007, 577–596. [5] G. Liu, Z. Yuan, Z. Qiu, S. Feng, Y. Xie, D. Leng, and X. Tian, Abrief review of bio-inspired surface technology and applicationtoward underwater drag reduction, Ocean Engineering, 199,2020, 106962. [6] R. Truesdell, A. Mammoli, P. Vorobieff, F. van Swol, andC.J. Brinker, Drag reduction on a patterned superhydrophobicsurface, Physical Review Letters, 97(4), 2006, 044504. [7] M. Saadat-Bakhsh, S.J. Asl, M.J. Kiani, and N.M. Nouri,Slip length measurement of pdms/hydrophobic silica superhy-drophobic coating for drag reduction application, Surface andCoatings Technology, 404, 2020, 126428. [8] M. Monfared, M.A. Alidoostan, and B. Saran Jam, Experimen-tal study on the friction drag reduction of superhydrophobicsurfaces in closed channel flow, Journal of Applied FluidMechanics, 12(1), 2019, 69–76. [9] R.J. Daniello, N.E. Waterhouse, and J.P. Rothstein, Dragreduction in turbulent flows over superhydrophobic surfaces,Physics of Fluids, 21(8), 2009, 085103. [10] H. Park, C.H. Choi, and C.J. Kim, Superhydrophobic dragreduction in turbulent flows, a critical review, Experiments inFluids, 62(11), 2021, 1–29. [11] G. Yunqing, L. Tao, M. Jiegang, S, Zhengzan, and Z,Peijian, Analysis of drag reduction methods and mechanismsof turbulent, Applied Bionics and Biomechanics, 2017(2017),1–8. [12] R. Costantini, J.P. Mollicone, and F. Battista, Drag reductioninduced by superhydrophobic surfaces in turbulent pipe flow,Physics of Fluids, 30(2), 2018, 025102. [13] M. Liravi, H. Pakzad, A. Moosavi, and A. Nouri-Borujerdi, Acomprehensive review on recent advances in superhydrophobicsurfaces and their applications for drag reduction, Progress inOrganic Coatings, 140, 2020, 105537. [14] Y. Cheng, J. Xu, and Y. Sui, Numerical study on dragreduction and heat transfer enhancement in microchannelswith superhydrophobic surfaces for electronic cooling, AppliedThermal Engineering, 88, 2015, 71–81. [15] Y. Li, K. Alame, and K. Mahesh, Feature-resolved compu-tational and analytical study of laminar drag reduction bysuperhydrophobic surfaces, Physical Review Fluids, 2(5), 2017,054002. [16] X.L., Wang, R. Zhang, and Q. Di, Progress in theories ofsuperhydrophobic surface slip effect and its application to dragreduction technology, Advances in Mechanics, 40(3), 2010,241–249. [17] K. Ellinas, A. Tseperi, and E. Gogolides, From superamphiphilic to amphiphilic polymeric surfaces with orderedhierarchical roughness fabricated with colloidal lithographyand plasma nanotexturing, Langmuir, 27, 2011, 3960–3969. [18] G.M. Mala and D.Q. Li, Flow characteristics of water inmicrotubes, International Journal of Heat and Fluid Flow,20(2), 1999, 142–148. [19] C.F. Liu, J.D. Yang, and Y.S. Ni, A multiplicative decom-position of Poiseuille number on rarefaction and roughnessby lattice Boltzmann simulation, Computers and Mathematicswith Applications, 61(12), 2011, 3528–3536. [20] M. Xu, A. Grabowski, N. Yu, J.W. Lee, and B.R. Pfeifer,Superhydrophobic drag reduction for turbulent flows in openwater, Physical Review Applied, 13(3), 2020, 034056.
Important Links:
Go Back
