Preparation of a Hydrophobic Copper Surface with Excellent Aging Properties Using Laser Shock Imprinting

Zongbao Shen; Chuang Li; Pin Li; Lei Zhang; Xiao Wang; Huixia Liu

doi:10.3788/LOP202259.1714006

[1] Lee K J, Lyu S N, Lee S M et al. Characteristics and self-cleaning effect of the transparent super-hydrophobic film having nanofibers array structures[J]. Applied Surface Science, 256, 6729-6735(2010).

[2] Zhu J Y, Wan H R, Hu X F. A rapid one-step process for the construction of corrosion-resistant bionic superhydrophobic surfaces[J]. Progress in Organic Coatings, 100, 56-62(2016).

[3] Qi Y L, Chen S J, Zhang J. Fluorine modification on titanium dioxide particles: improving the anti-icing performance through a very hydrophobic surface[J]. Applied Surface Science, 476, 161-173(2019).

[4] Pan R, Zhang H J, Zhong M L. Ultrafast laser hybrid fabrication and ice-resistance performance of a triple-scale micro/nano superhydrophobic surface[J]. Chinese Journal of Lasers, 48, 0202009(2021).

[5] Zhang F, Gao S J, Zhu Y Z et al. Alkaline-induced superhydrophilic/underwater superoleophobic polyacrylonitrile membranes with ultralow oil-adhesion for high-efficient oil/water separation[J]. Journal of Membrane Science, 513, 67-73(2016).

[6] Shen Z B, Zhang L, Li P et al. Altering the surface wettability of copper sheet using overlapping laser shock imprinting[J]. Applied Surface Science, 543, 148736(2021).

[7] Milionis A, Loth E, Bayer I S. Recent advances in the mechanical durability of superhydrophobic materials[J]. Advances in Colloid and Interface Science, 229, 57-79(2016).

[8] Zhu J Y. A novel fabrication of superhydrophobic surfaces on aluminum substrate[J]. Applied Surface Science, 447, 363-367(2018).

[9] Zhang X W, Zhou T, Liu J et al. Volcano-like hierarchical superhydrophobic surface synthesized via facile one-step secondary anodic oxidation[J]. Applied Surface Science, 540, 148337(2021).

[10] Zhang M J, Guo C F, Hu J. One-step fabrication of flexible superhydrophobic surfaces to enhance water repellency[J]. Surface and Coatings Technology, 400, 126155(2020).

[11] Zhou P Y, Peng Y Z, Huang Z M et al. Fabrication and droplet impact performance of superhydrophobic surfaces developed using nanosecond lasers[J]. Chinese Journal of Lasers, 47, 0402012(2020).

[12] Zhang Z B, Hua Y Q, Ye Y X et al. Fabrication of superhydrophobic nickel-aluminum bronze alloy surfaces based on picosecond laser pulses[J]. Chinese Journal of Lasers, 46, 0302013(2019).

[13] Wang D, Zhang Z Y, Zhang Z Y et al. Effects of picosecond laser parameters on surface wettability of cross-scale bionic mastoid-like texture[J]. China Surface Engineering, 34, 110-119(2021).

[14] Li C, Cheng G H, Razvan S. Investigation of femtosecond laser-induced periodic surface structure on tungsten[J]. Acta Optica Sinica, 36, 0532001(2016).

[15] Huang J H, Xu Z T, Li X N et al. An experimental study on a rapid micro imprinting process[J]. Journal of Materials Processing Technology, 283, 116716(2020).

[16] Koo S J, Kim H S. The homogeneity of multi-textured micro-pattern arrays in a laser shock surface patterning process and its effect on the surface properties of aluminum alloy[J]. Surface and Coatings Technology, 382, 125149(2020).

[17] Guo Y S, Sun X C, Yang X et al. Fabrication and controlling of metal sheets based on dynamic and mechanical effect of laser[J]. Laser & Optoelectronics Progress, 52, 081402(2015).

[18] Wang F. Theoretical and experimental research on laser shock forming[D], 73-86(2008).

[19] Zhang W H, Liu H X, Shen Z B et al. Experimental research on laser-shock flexible micro-forming of multilayer-metal composite sheets[J]. Chinese Journal of Lasers, 44, 0702001(2017).

[20] Luo X, Liu W J, Zhang H J et al. Ultrafast laser fabricating of controllable micro-nano dual-scale metallic surface structures and their functionalization[J]. Chinese Journal of Lasers, 48, 1502002(2021).

[21] Shen Z B, Zhang J D, Liu H X et al. Reducing the rebound effect in micro-scale laser dynamic flexible forming through using plasticine as pressure-carrying medium[J]. International Journal of Machine Tools and Manufacture, 141, 1-18(2019).

[22] Jin S Y, Wang Y X, Motlag M et al. Large-area direct laser-shock imprinting of a 3D biomimic hierarchical metal surface for triboelectric nanogenerators[J]. Advanced Materials, 30, 1705840(2018).

[23] Man J X, Zhao J Y, Yang H F et al. Study on laser shock imprinting nanoscale line textures on metallic foil and its application in nanotribology[J]. Materials & Design, 193, 108822(2020).

[24] Yang H F, Jia L, Liu K et al. High precision complete forming process of metal microstructure induced by laser shock imprinting[J]. The International Journal of Advanced Manufacturing Technology, 108, 143-155(2020).

[25] Man J X, Yang H F, Wang Y F et al. Study on controllable surface morphology of the micro-pattern fabricated on metallic foil by laser shock imprinting[J]. Optics & Laser Technology, 119, 105669(2019).

[26] Kim D G, Kim J G, Chu C N. Aging effect on the wettability of stainless steel[J]. Materials Letters, 170, 18-20(2016).

[27] Han J P, Cai M Y, Lin Y et al. 3D re-entrant nanograss on microcones for durable superamphiphobic surfaces via laser-chemical hybrid method[J]. Applied Surface Science, 456, 726-736(2018).

[28] Shen Z B, Wang X, Liu H X et al. Rubber-induced uniform laser shock wave pressure for thin metal sheets microforming[J]. Applied Surface Science, 327, 307-312(2015).

[29] Chen H, Yuan Z Q, Zhang J D et al. Preparation, characterization and wettability of porous superhydrophobic poly (vinyl chloride) surface[J]. Journal of Porous Materials, 16, 447-451(2009).