[1] Fu Y F, Yuan C Q, Bai X Q. Marine drag reduction of shark skin inspired riblet surfaces[J]. Biosurface and Biotribology, 3, 11-24(2017).

[2] Gray J. Studies in animal locomotion: the propulsive powers of the dolphin[J]. The Journal of Experimental Biology, 13, 192-199(1936).

[3] Kramer M O. Boundary layer stabilization by distributed damping[J]. Journal of the American Society for Naval Engineers, 72, 25-34(1960).

[4] Srivatsan L, Kumaran V. Flow induced instability of the interface between a fluid and a gel[J]. Journal De Physique Ii, 7, 947-963(1997).

[5] Muralikrishnan R, Kumaran V. Experimental study of the instability of the viscous flow past a flexible surface[J]. Physics of Fluids, 14, 775-780(2002).

[6] Gu Y Q, Zhao G, Zheng J X et al. Experimental and numerical investigation on drag reduction of non-smooth bionic jet surface[J]. Ocean Engineering, 81, 50-57(2014).

[7] Madavan N K, Deutsch S, Merkle C L. Measurements of local skin friction in a microbubble-modified turbulent boundary layer[J]. Journal of Fluid Mechanics, 156, 237-256(1985).

[8] Fuaad P A, Baig M F, Ahmad H. Drag-reduction in buoyant and neutrally-buoyant turbulent flows over super-hydrophobic surfaces in transverse orientation[J]. International Journal of Heat and Mass Transfer, 93, 1020-1033(2016).

[9] Bixler G D, Bhushan B. Fluid drag reduction with shark-skin riblet inspired microstructured surfaces[J]. Advanced Functional Materials, 23, 4507-4528(2013).

[10] Bacher E, Smith C. A combined visualization-anemometry study of the turbulent drag reducing mechanisms of triangular micro-groove surface modifications. [C]∥Shear Flow Control Conference. Reston, Virigina: AIAA, 1-10(1985).

[11] Dean B, Bhushan B. Shark-skin surfaces for fluid-drag reduction in turbulent flow: a review[J]. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 368, 4775-4806(2010).

[12] Bechert D W, Bruse M, Hage W et al. Experiments on drag-reducing surfaces and their optimization with an adjustable geometry[J]. Journal of Fluid Mechanics, 338, 59-87(1997).

[13] Denkena B, Köhler J, Wang B. Manufacturing of functional riblet structures by profile grinding[J]. CIRP Journal of Manufacturing Science and Technology, 3, 14-26(2010).

[14] Cong Q, Feng Y, Ren L Q. Affecting of riblets shape of nonsmooth surface on drag reduction[J]. Journal of Hydrodynamics, 21, 232-238(2006).

[15] Zhang D Y, Li Y Y, Han X et al. High-precision bio-replication of synthetic drag reduction shark skin[J]. Chinese Science Bulletin, 56, 938-944(2011).

[16] Chen H W, Zhang X, Zhang D Y et al. Large-scale equal-proportional amplification bio-replication of shark skin based on solvent-swelling PDMS[J]. Journal of Applied Polymer Science, 130, 2383-2389(2013).

[17] Bixler G D, Bhushan B. Bioinspired rice leaf and butterfly wing surface structures combining shark skin and lotus effects[J]. Soft Matter, 8, 11271-11284(2012).

[18] Hirt G, Thome M. Large area rolling of functional metallic micro structures[J]. Production Engineering, 1, 351-356(2007).

[19] Kim T, Shin R, Jung M et al. Drag reduction using metallic engineered surfaces with highly ordered hierarchical topographies: nanostructures on micro-riblets[J]. Applied Surface Science, 367, 147-152(2016).

[20] Zhang S, Zeng X. Matthews D T A, et al. Selection of micro-fabrication techniques on stainless steel sheet for skin friction[J]. Friction, 4, 89-104(2016).

[21] Bixler G D, Bhushan B. Shark skin inspired low-drag microstructured surfaces in closed channel flow[J]. Journal of Colloid and Interface Science, 393, 384-396(2013).

[22] Long J Y, Wu Y C, Gong D W et al. Femtosecond laser fabricated superhydrophobic copper surfaces and their anti-icing properties[J]. Chinese Journal of Lasers, 42, 0706002(2015).

[23] Lin C, Zhong M L, Fan P X et al. Picosecond laser fabrication of large-area surface micro-nano lotus-leaf structures and replication of superhydrophobic silicone rubber surfaces[J]. Chinese Journal of Lasers, 41, 0903007(2014).

[24] Qin X Y, Huang T, Xiao R S. Periodic microstructure on Ti surface induced by high-power green femtosecond laser[J]. Chinese Journal of Lasers, 46, 1002006(2019).

[25] Yin K, Dong X R, Zhang F et al. Superamphiphobic miniature boat fabricated by laser micromachining[J]. Applied Physics Letters, 110, 121909(2017).

[26] Long J Y, Pan L, Fan P X et al. Cassie-state stability of metallic superhydrophobic surfaces with various micro/nanostructures produced by a femtosecond laser[J]. Langmuir, 32, 1065-1072(2016).

[27] Amoruso S, Ausanio G, Barone A C et al. Ultrashort laser ablation of solid matter in vacuum: a comparison between the picosecond and femtosecond regimes[J]. Journal of Physics B, 38, L329-L338(2005).

[28] Fan P X, Bai B F, Zhong M L et al. General strategy toward dual-scale-controlled metallic micro-nano hybrid structures with ultralow reflectance[J]. ACS Nano, 11, 7401-7408(2017).

[29] Liu Z H, Dong W C, Xiong Y. Numerical analysis of the effect of Reynolds number on drag reduction by grooved surface[J]. Journal of Naval University of Engineering, 19, 6-11(2007).

[30] Luchini P, Manzo F, Pozzi A. Resistance of a grooved surface to parallel flow and cross-flow[J]. Journal of Fluid Mechanics, 228, 87-109(1991).

[31] Wenzel R N. Resistance of solid surfaces to wetting by water[J]. Industrial & Engineering Chemistry, 28, 988-994(1936).

[32] Liu Y, Cao H J, Chen S G et al. Ag nanoparticle-loaded hierarchical superamphiphobic surface on an Al substrate with enhanced anticorrosion and antibacterial properties[J]. Journal of Physical Chemistry C, 119, 25449-25456(2015).

[33] Liu Y, Li S Y, Wang Y M et al. Superhydrophobic and superoleophobic surface by electrodeposition on magnesium alloy substrate: wettability and corrosion inhibition[J]. Journal of Colloid and Interface Science, 478, 164-171(2016).

[34] Conradi M, Sever T. Gregor i P, et al. Short- and long-term wettability evolution and corrosion resistance of uncoated and polymer-coated laser-textured steel surface[J]. Coatings, 9, 592(2019).

[35] Long J Y, Fan P X, Gong D W et al. Ultrafast laser fabricated bio-inspired surfaces with special wettability[J]. Chinese Journal of Lasers, 43, 0800001(2016).

[36] Allara D L, Nuzzo R G. Spontaneously organized molecular assemblies. 2. Quantitative infrared spectroscopic determination of equilibrium structures of solution-adsorbed n-alkanoic acids on an oxidized aluminum surface[J]. Langmuir, 1, 52-66(1985).

[37] Wang S T, Feng L, Liu H et al. Manipulation of surface wettability between superhydrophobicity and superhydrophilicity on copper films[J]. Chemphyschem, 6, 1475-1478(2005).

[38] Lei X, Lin N M, Zou J J et al. Research progress of micro-arc oxidation on aluminum alloys[J]. Surface Technology, 48, 10-22(2019).

[39] Feng J X, Hu H B, Lu B J et al. Experimental study on drag reduction characteristics of superhydrophobic groove surfaces with ventilation[J]. Chinese Journal of Theoretical and Applied Mechanics, 52, 24-30(2020).