This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Wang Q, Xu SS, Xing XT, Wang N. Progress in fabrication and applications of micro/nanostructured superhydrophobic surfaces. Surf Innov. 2022;10:89-110.WangQXuSSXingXTWangN.Progress in fabrication and applications of micro/nanostructured superhydrophobic surfaces..2022;10:89-110.Search in Google Scholar
Yang Y, Li XL, Zheng X, Chen ZY, Zhou QF, Chen Y. 3D-printed biomimetic super-hydrophobic structure for microdroplet manipulation and oil/water separation. Adv Mater. 2018;30.YangYLiXLZhengXChenZYZhouQFChenY.3D-printed biomimetic super-hydrophobic structure for microdroplet manipulation and oil/water separation..2018;30.Search in Google Scholar
Zhang SN, Huang JY, Chen Z, Lai YK. Bioinspired special wettability surfaces: from fundamental research to water harvesting applications. Small. 2017;13.ZhangSNHuangJYChenZLaiYK.Bioinspired special wettability surfaces: from fundamental research to water harvesting applications..2017;13.Search in Google Scholar
Zhu H, Guo ZG, Liu MM. Biomimetic watercollecting materials inspired by nature. Chem Commun. 2016;52:3863-79.ZhuHGuoZGLiuMM.Biomimetic watercollecting materials inspired by nature..2016;52:3863-79.Search in Google Scholar
Zheng YM, Gao SF, Jiang L. Directional adhesion of superhydrophobic butterfly wings. J Soft Matter 2007;3:178-82.ZhengYMGaoSFJiangL.Directional adhesion of superhydrophobic butterfly wings.2007;3:178-82.Search in Google Scholar
Yang L, Shen XD, Yang Q, Liu JQ, Wu WJ, Li DY, et al. Fabrication of biomimetic anisotropic superhydrophobic surface with rice leaf-like structures by femtosecond laser. Opt Mater. 2021;112.YangLShenXDYangQLiuJQWuWJLiDYFabrication of biomimetic anisotropic superhydrophobic surface with rice leaf-like structures by femtosecond laser..2021;112.Search in Google Scholar
Chen HW, Zhang PF, Zhang LW, Iu HLL, Jiang X, Zhang DY, et al. Continuous directional water transport on the peristome surface of Nepenthes alata. Nature. 2016;532:85-+.ChenHWZhangPFZhangLWIuHLLJiangXZhangDYContinuous directional water transport on the peristome surface of Nepenthes alatas..2016;532:85-+.Search in Google Scholar
Feng SL, Zhu PA, Zheng HX, Zhan HY, Chen C, Li JQ, et al. Three-dimensional capillary ratchet-induced liquid directional steering, Science. 2021;373:1344-+.xFengSLZhuPAZhengHXZhanHYChenCLiJQThree-dimensional capillary ratchet-induced liquid directional steering,.2021;373:1344-+.xSearch in Google Scholar
Hu BB, Duan ZF, Xu BJ, Zhang KJ, Tang ZX, Lu C, et al. Ultrafast self-propelled directional liquid transport on the pyramid-structured fibers with concave curved surfaces. J Am Chem Soc. 2020;142:6111-6.HuBBDuanZFXuBJZhangKJTangZXLuCUltrafast self-propelled directional liquid transport on the pyramid-structured fibers with concave curved surfaces..2020;142:6111-6.Search in Google Scholar
Li, Li JQ, Dong. Bioinspired topological surface for directional oil lubrication. ACS Appl Mater Interfaces. 2020;12:5113-9.LiDong.Li JQBioinspired topological surface for directional oil lubrication..2020;12:5113-9.Search in Google Scholar
Zheng YM, Bai H, Huang ZB, Tian XL, Nie FQ, Zhao Y, et al. Directional water collection on wetted spider silk. Nature. 2010;463:640-3.ZhengYMBaiHHuangZBTianXLNieFQZhaoYDirectional water collection on wetted spider silk..2010;463:640-3.Search in Google Scholar
Wang LX, Zhang SY, Li SS, Yang SX, Dong SY. Inner surface of Nepenthes slippery zone: ratchet effect of lunate cells causes anisotropic superhydrophobicity. R Soc Open Sci. 2020;7.WangLXZhangSYLiSSYangSXDongSY.Inner surface of Nepenthes slippery zone: ratchet effect of lunate cells causes anisotropic superhydrophobicity..2020;7.Search in Google Scholar
Zhang PF, Chen HW, Li L, Liu HL, Liu G, Zhang LW, et al. Bioinspired smart peristome Ssurface for temperature-controlled unidirectional water spreading. ACS Appl Mater Interfaces. 2017;9:5645-52.ZhangPFChenHWLiLLiuHLLiuGZhangLWBioinspired smart peristome Ssurface for temperature-controlled unidirectional water spreading..2017;9:5645-52.Search in Google Scholar
Barraza B, Olate-Moya F, Montecinos G, Ortega JH, Rosenkranz A, Tamburrino A, Palza H. Superhydrophobic SLA 3D printed materials modified with nanoparticles biomimicking the hierarchical structure of a rice leaf. Sci Technol Adv Mater 2022;23:300-21.BarrazaBOlate-MoyaFMontecinosGOrtegaJHRosenkranzATamburrinoAPalzaH.Superhydrophobic SLA 3D printed materials modified with nanoparticles biomimicking the hierarchical structure of a rice leaf.2022;23:300-21.Search in Google Scholar
Yunusa M, Ozturk FE, Yildirim A, Tuvshindorj U, Kanik M, Bayindir M. Bio-inspired hierarchically structured polymer fibers for anisotropic non-wetting surfaces. RSC Adv. 2017;7:15553-60.YunusaMOzturkFEYildirimATuvshindorjUKanikMBayindirM.Bio-inspired hierarchically structured polymer fibers for anisotropic non-wetting surfaces..2017;7:15553-60.Search in Google Scholar
Yong JL, Yang Q, Chen F, Zhang DS, Farooq U, Du GQ, Hou X. A simple way to achieve superhydrophobicity, controllable water adhesion, anisotropic sliding, and anisotropic wetting based on femtosecond-laser-induced line-patterned surfaces. J Mater Chem A. 2014;2: 5499-507.YongJLYangQChenFZhangDSFarooqUDuGQHouX.A simple way to achieve superhydrophobicity, controllable water adhesion, anisotropic sliding, and anisotropic wetting based on femtosecond-laser-induced line-patterned surfaces..2014;2:5499-507.Search in Google Scholar
Chung JY, Youngblood JP, Stafford CM. Anisotropic wetting on tunable micro-wrinkled surfaces. J Soft Mat ter. 2007;3:1163-9.ChungJYYoungbloodJPStaffordCM.Anisotropic wetting on tunable micro-wrinkled surfaces..2007;3:1163-9.Search in Google Scholar
Huang JH, Xu XT, Li SN, Peng LF, Lai XM. An experimental study on a rapid micro imprinting process. J Mater Proc Technol. 2020;283.HuangJHXuXTLiSNPengLFLaiXM.An experimental study on a rapid micro imprinting process..2020;283.Search in Google Scholar
Shen ZB, Zhang L, Li P, Liu HX, Liu K, Lin XY, et al. Altering the surface wettability of copper sheet using overlapping laser shock imprinting. Appl Surf Sci. 2021;543.ShenZBZhangLLiPLiuHXLiuKLinXYAltering the surface wettability of copper sheet using overlapping laser shock imprinting..2021;543.Search in Google Scholar
Jin SY, Wang YX, Motlag M, Gao SJ, Xu J, Nian Q, et al. Large-area direct laser-shock imprinting of a 3D biomimic hierarchical metal surface for triboelectric nanogenerators. Adv Mater. 2018;30.JinSYWangYXMotlagMGaoSJXuJNianQLarge-area direct laser-shock imprinting of a 3D biomimic hierarchical metal surface for triboelectric nanogenerators..2018;30.Search in Google Scholar
Man JX, Zhao JY, Yang HF, Song LC, Liu D. Study on laser shock imprinting nanoscale line textures on metallic foil and its application in nanotribology. Mater Design. 2020;193.ManJXZhaoJYYangHFSongLCLiuD.Study on laser shock imprinting nanoscale line textures on metallic foil and its application in nanotribology..2020;193.Search in Google Scholar
Yang HF, Jia L, Liu K, Wang Y, Xiong F, Liu H, Hao JB. High precision complete forming process of metal microstructure induced by laser shock imprinting. Int J Adv Manufact Technol. 2020;108:143-55.YangHFJiaLLiuKWangYXiongFLiuHHaoJB.High precision complete forming process of metal microstructure induced by laser shock imprinting..2020;108:143-55.Search in Google Scholar
Choi DC, Kim HS. Performance evaluation of laser shock micro-patterning process on aluminum surface with various process parameters and loading schemes. Opt Lasers \Eng. 2020;124.ChoiDCKimHS.Performance evaluation of laser shock micro-patterning process on aluminum surface with various process parameters and loading schemes..2020;124.Search in Google Scholar
Zhang BC, Yang HF, Xiong F, Liu H, Hao JB, Liu XH. Research on the transient forming process and high-temperature stability mechanism of warm laser shock imprinting. Opt Lasers Eng. 2021;146.ZhangBCYangHFXiongFLiuHHaoJBLiuXH.Research on the transient forming process and high-temperature stability mechanism of warm laser shock imprinting..2021;146.Search in Google Scholar
Man JX, Yang HF, Wang YF, Chen HX, Xiong F. Study on controllable surface morphology of the micro-pattern fabricated on metallic foil by laser shock imprinting. Opt Lasers \Technol. 2019;119.ManJXYangHFWangYFChenHXXiongF.Study on controllable surface morphology of the micro-pattern fabricated on metallic foil by laser shock imprinting..2019;119.Search in Google Scholar
Riedel M, Eichner A, Jetter R. Slippery surfaces of carnivorous plants: composition of epicuticular wax crystals in Nepenthes alata Blanco pitchers. Planta. 2003;218:87-97.RiedelMEichnerAJetterR.Slippery surfaces of carnivorous plants: composition of epicuticular wax crystals in Nepenthes alata Blanco pitchers..2003;218:87-97.Search in Google Scholar
Zhang WW, Yao YL. Micro scale laser shock processing of metallic components. J Manufact Sci Eng-Trans ASME. 2002;124:369-78.ZhangWWYaoYL.Micro scale laser shock processing of metallic components..2002;124:369-78.Search in Google Scholar
Wang SL, Yu NZ, Wang TQ, Ge P, Ye SS, Xue PH, et al. Morphology-patterned anisotropic Wetting surface for fluid control and gas-liquid separation in microfluidics. ACS Appl Mater Interfaces. 2016;8:13094-103.WangSLYuNZWangTQGePYeSSXuePHMorphology-patterned anisotropic Wetting surface for fluid control and gas-liquid separation in microfluidics..2016;8:13094-103.Search in Google Scholar
Jing X, Si WF, Sun J, Zhou JK, Lin JQ, Yu BJ, Lu MM. Wettability and droplet directional spread investigation of Crescent array surface inspired by slippery zone of Nepenthes. Adv Mater Interfaces. 2022;9.JingXSiWFSunJZhouJKLinJQYuBJLuMM.Wettability and droplet directional spread investigation of Crescent array surface inspired by slippery zone of Nepenthes..2022;9.Search in Google Scholar
Wang LX, Yin K, Deng QW, Huang QQ, He J, Duan JA. Wetting ridge-guided directional water self-transport. Adv Sci. 2022;9.WangLXYinKDengQWHuangQQHeJDuanJA.Wetting ridge-guided directional water self-transport..2022;9.Search in Google Scholar