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清华大学学报(自然科学版)  2024, Vol. 64 Issue (3): 393-408    DOI: 10.16511/j.cnki.qhdxxb.2024.26.009
  生物摩擦学前沿 本期目录 | 过刊浏览 | 高级检索 |
仿生超滑涂层研究进展
邱豪楠, 刘威, 唐悦, 王胡军, 郑靖
西南交通大学 机械工程学院, 摩擦学研究所, 成都 610031
Research progress in bioinspired slippery coatings
QIU Haonan, LIU Wei, TANG Yue, WANG Hujun, ZHENG Jing
Tribology Research Institute, School of Mechanical Engineering, Southwest Jiaotong University, Chengdu 610031, China
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摘要 仿生超滑涂层因具有优异的拒液性、自愈性和高压稳定性,在防污、抗黏附和防结冰等应用领域受到广泛关注。将润滑油注入多孔基体获得的注液超滑涂层或在光滑平面接枝润滑分子获得的类液体超滑涂层均可获得上述优异性能。然而,超滑涂层面临润滑层易损耗、机械稳定性不足等问题,在实际应用中仍存在一定局限性。该文在总结注液超滑表面仿生设计原理的基础上,详细介绍了注液超滑涂层和类液体超滑涂层的特点与研究进展,并指出当前面临的问题。此外,从高可靠性、长寿命超滑涂层的优化设计制造角度,评述了超滑涂层的发展趋势。
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邱豪楠
刘威
唐悦
王胡军
郑靖
关键词 超滑涂层仿生设计表面结构润滑油稳定性    
Abstract:[Significance] Bioinspired slippery coatings have attracted extensive attention in antifouling, anti-adhesion, and anti-icing applications because of their excellent liquid repellency, self-healing properties, and high-pressure stability. The slippery liquid-infused coating obtained by infusing lubricating oil into porous matrixes and the slippery liquid-like coating afforded by grafting lubricating molecules onto smooth surfaces exhibit the aforementioned properties. However, some limitations still hinder the practical applications of these coatings, such as easy loss of the lubrication layer and insufficient mechanical stability. Therefore, this study introduces the characteristics and research progress of slippery liquid-infused and slippery liquid-like coatings in detail by summarizing the bionic design principles of slippery liquid-infused surfaces. Furthermore, the existing problems related to coatings are highlighted. [Progress] According to the oil fixation mechanism and lubrication layer thickness, slippery coatings could be divided into three categories. Type 1D slippery coatings, known as slippery liquid-like coatings, mainly stabilize the lubrication layer by chemical grafting; thus, they showed good stability when subjected to gravity, shear force, and water scouring. However, they easily lost their slippery performance when subjected to mechanical wear due to their low thickness and poor wear resistance. The fabrication of type 1D-slippery coatings involved complex preparation processes, harsh preparation conditions, and high costs, limiting their large-scale applications. Type 2D- and 3D-slippery coatings stabilized the lubrication layer through their porous structures. Type 2D-slippery coatings exhibited good mechanical stability and could be easily prepared. However, due to their poor oil-fixing performance, the lubricating oil was easily lost, and they could not recover the oil themselves. Therefore, maintaining their slippery properties for a long time under harsh conditions was challenging. To solve this problem, researchers had conducted several studies on structural design and chemical modification. Despite their effective efforts, the porous structures of type 2D-slippery coatings could only store a small amount of lubricating oil, and the timely replenishment of oil after oil loss remained difficult. Type 3D-slippery coatings included gel and nongel coatings. Gel cross-linked networks and 3D porous physical structures could store/release lubricating oil, thereby improving the slippery stability of these coatings. With the introduction of smart materials, type 3D-slippery coatings could actively adjust the release of lubricating oil according to changes in the environment and coating states. However, the 3D-gel and -nongel slippery coatings exhibited insufficient mechanical stability and weaked oil control-release ability, respectively. [Conclusions and Prospects] To prepare highly reliable and long-life slippery coatings for large-scale industrial applications, further research is required. First, we need to understand the storage, fixation, and release mechanisms of the lubricating oil in slippery coatings, introduce intelligent materials, and systematically study the influence of structural characteristics, chemical compositions, and preparation methods on the stability of coatings. Second, the influence of lubricating oil on the adhesive strength of coatings must be further investigated because the lubricating oil may affect the bonding properties between the coatings and substrates. Additionally, the coating preparation methods should be simplified, and costs must be reduced to promote the applications of bioinspired slippery coatings. To achieve green production, more attention should be paid to the use of environmentally friendly materials in coating preparation processes. Finally, new slippery coatings need to be developed according to practical application environments by mimicking multiple biological templates.
Key wordsslippery coating    bionic design    surface structure    lubricating oil    stability
收稿日期: 2023-09-05      出版日期: 2024-03-06
基金资助:四川省科技计划项目(2023NSFSC0863);国家自然科学基金资助项目(52105212);中国博士后科学基金项目(2021M702712)
通讯作者: 王胡军,助理教授,E-mail:hjwang20@swjtu.edu.cn     E-mail: hjwang20@swjtu.edu.cn
作者简介: 邱豪楠(1999—),男,硕士研究生。
引用本文:   
邱豪楠, 刘威, 唐悦, 王胡军, 郑靖. 仿生超滑涂层研究进展[J]. 清华大学学报(自然科学版), 2024, 64(3): 393-408.
QIU Haonan, LIU Wei, TANG Yue, WANG Hujun, ZHENG Jing. Research progress in bioinspired slippery coatings. Journal of Tsinghua University(Science and Technology), 2024, 64(3): 393-408.
链接本文:  
http://jst.tsinghuajournals.com/CN/10.16511/j.cnki.qhdxxb.2024.26.009  或          http://jst.tsinghuajournals.com/CN/Y2024/V64/I3/393
  
  
  
  
  
  
  
  
[1] DENG R, SHEN T, CHEN H L, et al. Slippery liquid-infused porous surfaces (SLIPSs):A perfect solution to both marine fouling and corrosion?[J]. Journal of Materials Chemistry A, 2020, 8(16):7536-7547.
[2] YAN W H, XUE S Y, XIANG B, et al. Recent advances of slippery liquid-infused porous surfaces with anti-corrosion[J]. Chemical Communications, 2023, 59(16):2182-2198.
[3] HAN X, WU J H, ZHANG X H, et al. Special issue on advanced corrosion-resistance materials and emerging applications. The progress on antifouling organic coating:From biocide to biomimetic surface[J]. Journal of Materials Science & Technology, 2021, 61:46-62.
[4] LATTHE S S, SUTAR R S, BHOSALE A K, et al. Recent developments in air-trapped superhydrophobic and liquid-infused slippery surfaces for anti-icing application[J]. Progress in Organic Coatings, 2019, 137:105373.
[5] LV J Y, SONG Y L, JIANG L, et al. Bio-inspired strategies for anti-icing[J]. ACS Nano, 2014, 8(4):3152-3169.
[6] OLAD A, MARYAMI F, MIRMOHSENI A, et al. Potential of slippery liquid infused porous surface coatings as flashover inhibitors on porcelain insulators in icing, contaminated, and harsh environments[J]. Progress in Organic Coatings, 2021, 151:106082.
[7] SCHULTZ M P, BENDICK J A, HOLM E R, et al. Economic impact of biofouling on a naval surface ship[J]. Biofouling, 2011, 27(1):87-98.
[8] SALTA M, WHARTON J A, STOODLEY P, et al. Designing biomimetic antifouling surfaces[J]. Philosophical Transactions of the Royal Society A:Mathematical, Physical and Engineering Sciences, 2010, 368(1929):4729-4754.
[9] LEJARS M, MARGAILLAN A, BRESSY C. Fouling release coatings:A nontoxic alternative to biocidal antifouling coatings[J]. Chemical Reviews, 2012, 112(8):4347-4390.
[10] JOHNSON C L. Wing loading, icing and associated aspects of modern transport design[J]. Journal of the Aeronautical Sciences, 1940, 8(2):43-54.
[11] 赵一鉴, 燕则翔, 苏建民, 等. 仿生防冰表面研究进展[J]. 表面技术, 2021, 50(10):29-39. ZHAO Y J, YAN Z X, SU J M, et al. Research progress of biomimetic anti-icing surface[J]. Surface Technology, 2021, 50(10):29-39. (in Chinese)
[12] MAGIN C M, COOPER S P, BRENNAN A B. Non-toxic antifouling strategies[J]. Materials Today, 2010, 13(4):36-44.
[13] WANG Z J. Recent progress on ultrasonic de-icing technique used for wind power generation, high-voltage transmission line and aircraft[J]. Energy and Buildings, 2017, 140:42-49.
[14] 周峰, 吴杨. "润滑"之新解[J]. 摩擦学学报, 2016, 36(1):132-136. ZHOU F, WU Y. A novel insight into "lubrication"[J]. Tribology, 2016, 36(1):132-136. (in Chinese)
[15] BARTHLOTT W, NEINHUIS C. Purity of the sacred lotus, or escape from contamination in biological surfaces[J]. Planta, 1997, 202(1):1-8.
[16] SULTONZODA F, 王晶, 周瑾萱, 等. 超疏水铝合金表面的制备、耐腐蚀及防污性能[J]. 中国有色金属学报, 2020, 30(10):2316-2321. SULTONZODA F, WANG J, ZHOU J X, et al. Fabrication, anti-corrosion and antifouling performance of superhydrophobic aluminum alloy surface[J]. The Chinese Journal of Nonferrous Metals, 2020, 30(10):2316-2321. (in Chinese)
[17] 颜薪瞩, 李立浧, 李剑, 等. 甲基硅树脂超疏水涂层的防污闪性能[J]. 高电压技术, 2018, 44(9):2835-2843. YAN X Z, LI L C, LI J, et al. Anti-pollution flashover performance of methyl silicone resin superhydrophobic coating[J]. High Voltage Engineering, 2018, 44(9):2835-2843. (in Chinese)
[18] 李玥, 卢亚妹, 王鹏飞, 等. 透明超疏水材料的制备及其应用[J]. 化学进展, 2021, 33(12):2362-2377. LI Y, LU Y M, WANG P F, et al. Preparation and application of transparent superhydrophobic materials[J]. Progress in Chemistry, 2021, 33(12):2362-2377. (in Chinese)
[19] 舒忠虎, 鲍江涌, 陈标, 等. 基于磁控溅射-氟化改性的新型ZnO/SiO2复合超疏水涂层防冰性能研究[J]. 表面技术, 2022, 51(8):452-459. SHU Z H, BAO J Y, CHEN B, et al. Research on anti-ice performance of a novel ZnO/SiO2 composite superhydrophobic coating modified by magnetron sputtering and fluoridation[J]. Surface Technology, 2022, 51(8):452-459. (in Chinese)
[20] SU B, TIAN Y, JIANG L. Bioinspired interfaces with superwettability:From materials to chemistry[J]. Journal of the American Chemical Society, 2016, 138(6):1727-1748.
[21] DENG X, MAMMEN L, BUTT H J, et al. Candle soot as a template for a transparent robust superamphiphobic coating[J]. Science, 2012, 335(6064):67-70.
[22] LU Y, SATHASIVAM S, SONG J L, et al. Robust self-cleaning surfaces that function when exposed to either air or oil[J]. Science, 2015, 347(6226):1132-1135.
[23] WONG T S, KANG S H, TANG S K Y, et al. Bioinspired self-repairing slippery surfaces with pressure-stable omniphobicity[J]. Nature, 2011, 477(7365):443-447.
[24] CHEN H W, ZHANG P F, ZHANG L W, et al. Continuous directional water transport on the peristome surface of Nepenthes alata[J]. Nature, 2016, 532(7597):85-89.
[25] CAO M Y, GUO D W, YU C M, et al. Water-repellent properties of superhydrophobic and lubricant-infused "slippery" surfaces:A brief study on the functions and applications[J]. ACS Applied Materials & Interfaces, 2016, 8(6):3615-3623.
[26] CAO M Y, JIN X, PENG Y, et al. Unidirectional wetting properties on multi-bioinspired magnetocontrollable slippery microcilia[J]. Advanced Materials, 2017, 29(23):1606869.
[27] WANG Y, XIAO L D, ULLAH S, et al. Evaluation of a nurse-led dementia education and knowledge translation programme in primary care:A cluster randomized controlled trial[J]. Nurse Education Today, 2017, 49:1-7.
[28] 吴德全, 张达威, 刘贝, 等. 超滑表面(LIS/SLIPS)的设计与制备研究进展[J]. 表面技术, 2019, 48(1):90-101. WU D Q, ZHANG D W, LIU B, et al. Research progress for desigh and fabrication of LIS/SLIPS[J]. Surface Technology, 2019, 48(1):90-101. (in Chinese)
[29] PRESTON D J, SONG Y, LU Z M, et al. Design of lubricant infused surfaces[J]. ACS Applied Materials & Interfaces, 2017, 9(48):42383-42392.
[30] SMITH J D, DHIMAN R, ANAND S, et al. Droplet mobility on lubricant-impregnated surfaces[J]. Soft Matter, 2013, 9(6):1772-1780.
[31] PEPPOU-CHAPMAN S, HONG J K, WATERHOUSE A, et al. Life and death of liquid-infused surfaces:A review on the choice, analysis and fate of the infused liquid layer[J]. Chemical Society Reviews, 2020, 49(11):3688-3715.
[32] 赵仕东, 周树学. 超滑氟硅涂层研究进展[J]. 涂料工业, 2023, 53(8):82-88. ZHAO S D, ZHOU S X. Research progress of fluoro/silicone based ultra-slippery coating[J]. Paint & Coatings Industry, 2023, 53(8):82-88. (in Chinese)
[33] WANG L M, MCCARTHY T J. Covalently attached liquids:Instant omniphobic surfaces with unprecedented repellency[J]. Angewandte Chemie International Edition, 2016, 55(1):244-248.
[34] ZHU Y F, MCHALE G, DAWSON J, et al. Slippery liquid-like solid surfaces with promising antibiofilm performance under both static and flow conditions[J]. ACS Applied Materials & Interfaces, 2022, 14(5):6307-6319.
[35] HAO X Q, SUN Z R, WU S W, et al. Self-lubricative organic-inorganic hybrid coating with anti-icing and anti-waxing performances by grafting liquid-like polydimethylsiloxane[J]. Advanced Materials Interfaces, 2022, 9(18):2200160.
[36] ZHAO H Y, DESHPANDE C A, LI L N, et al. Extreme antiscaling performance of slippery omniphobic covalently attached liquids[J]. ACS Applied Materials & Interfaces, 2020, 12(10):12054-12067.
[37] HUANG W J, YANG J C, ZHANG C H, et al. Durable and versatile liquid-like surfaces via the base-triggered synthesis of polysiloxane[J]. ACS Applied Polymer Materials, 2023, 5(6):4578-4587.
[38] ZHAO H Y, KHODAKARAMI S, DESHPANDE C A, et al. Scalable slippery omniphobic covalently attached liquid coatings for flow fouling reduction[J]. ACS Applied Materials & Interfaces, 2021, 13(32):38666-38679.
[39] LESLIE D C, WATERHOUSE A, BERTHET J B, et al. A bioinspired omniphobic surface coating on medical devices prevents thrombosis and biofouling[J]. Nature Biotechnology, 2014, 32(11):1134-1140.
[40] MA J, PAN W H, LI Y H, et al. Slippery coating without loss of lubricant[J]. Chemical Engineering Journal, 2022, 444:136606.
[41] SHENG Z Z, DING Y, LI G Y, et al. Solid-liquid host-guest composites:The marriage of porous solids and functional liquids[J]. Advanced Materials, 2021, 33(52):2104851.
[42] LIU H, WANG Y D, HUANG J Y, et al. Bioinspired surfaces with superamphiphobic properties:Concepts, synthesis, and applications[J]. Advanced Functional Materials, 2018, 28(19):1707415.
[43] 赵书瑞, 申婷, 李玉堂, 等. 基于呼吸图法的环氧树脂基超滑液体灌注防冰涂层[J]. 高分子学报, 2021, 52(12):1622-1631. ZHAO S R, SHEN T, LI Y T, et al. Epoxy-resin-based slippery liquid infused anti-icing coating based on breath figure[J]. Acta Polymerica Sinica, 2021, 52(12):1622-1631. (in Chinese)
[44] KIM P, KREDER M J, ALVARENGA J, et al. Hierarchical or not? Effect of the length scale and hierarchy of the surface roughness on omniphobicity of lubricant-infused substrates[J]. Nano Letters, 2013, 13(4):1793-1799.
[45] ZHANG M L, SUN G H, GUO H, et al. Effect of morphology evolution on the anticorrosion performance of superhydrophobic surfaces and lubricant-infused surfaces[J]. ACS Sustainable Chemistry & Engineering, 2020, 8(8):3170-3180.
[46] YAN Y X, WANG J H, GAO J, et al. TiO2-based slippery liquid-infused porous surfaces with excellent ice-phobic performance[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2022, 654:129994.
[47] LONG Y F, YIN X X, MU P, et al. Slippery liquid-infused porous surface (SLIPS) with superior liquid repellency, anti-corrosion, anti-icing and intensified durability for protecting substrates[J]. Chemical Engineering Journal, 2020, 401:126137.
[48] MAJI K, DAS A, HIRTZ M, et al. How does chemistry influence liquid wettability on liquid-infused porous surface?[J]. ACS Applied Materials & Interfaces, 2020, 12(12):14531-14541.
[49] SOTIRI I, TAJIK A, LAI Y, et al. Tunability of liquid-infused silicone materials for biointerfaces[J]. Biointerphases, 2018, 13(6):06D401.
[50] YONG J L, CHEN F, YANG Q, et al. Nepenthes inspired design of self-repairing omniphobic slippery liquid infused porous surface (SLIPS) by femtosecond laser direct writing[J]. Advanced Materials Interfaces, 2017, 4(20):1700552.
[51] HAN X, TANG X, CHEN R F, et al. Citrus-peel-like durable slippery surfaces[J]. Chemical Engineering Journal, 2021, 420:129599.
[52] ZHANG M L, LIU Q, CHEN R R, et al. Lubricant-infused coating by double-layer ZnO on aluminium and its anti-corrosion performance[J]. Journal of Alloys and Compounds, 2018, 764:730-737.
[53] SUN H Y, LEI F, LI T, et al. Facile fabrication of novel multifunctional lubricant-infused surfaces with exceptional tribological and anticorrosive properties[J]. ACS Applied Materials & Interfaces, 2021, 13(5):6678-6687.
[54] DAMLE V G, TUMMALA A, CHANDRASHEKAR S, et al. "Insensitive" to touch:Fabric-supported lubricant-swollen polymeric films for omniphobic personal protective gear[J]. ACS Applied Materials & Interfaces, 2015, 7(7):4224-4232.
[55] CUI J X, DANIEL D, GRINTHAL A, et al. Dynamic polymer systems with self-regulated secretion for the control of surface properties and material healing[J]. Nature Materials, 2015, 14(8):790-795.
[56] RAO Q Q, ZHANG J W, ZHAN X L, et al. UV-driven self-replenishing slippery surfaces with programmable droplet-guiding pathways[J]. Journal of Materials Chemistry A, 2020, 8(5):2481-2489.
[57] YAO X, WU S W, CHEN L, et al. Self-replenishable anti-waxing organogel materials[J]. Angewandte Chemie International Edition, 2015, 54(31):8975-8979.
[58] ZHAO B, BRITTAIN W J. Polymer brushes:Surface-immobilized macromolecules[J]. Progress in Polymer Science, 2000, 25(5):677-710.
[59] MA S H, ZHANG X Q, YU B, et al. Brushing up functional materials[J]. NPG Asia Materials, 2019, 11(1):24.
[60] EDMONDSON S, OSBORNE V L, HUCK W T S. Polymer brushes via surface-initiated polymerizations[J]. Chemical Society Reviews, 2004, 33(1):14-22.
[61] BARBEY R, LAVANANT L, PARIPOVIC D, et al. Polymer brushes via surface-initiated controlled radical polymerization:Synthesis, characterization, properties, and applications[J]. Chemical Reviews, 2009, 109(11):5437-5527.
[62] KRUMPFER J W, MCCARTHY T J. Contact angle hysteresis:A different view and a trivial recipe for low hysteresis hydrophobic surfaces[J]. Faraday Discussions, 2010, 146:103-111.
[63] SARMA J, ZHANG L, GUO Z Q, et al. Sustainable icephobicity on durable quasi-liquid surface[J]. Chemical Engineering Journal, 2022, 431:133475.
[64] GRESHAM I J, NETO C. Advances and challenges in slippery covalently-attached liquid surfaces[J]. Advances in Colloid and Interface Science, 2023, 315:102906.
[65] SINGH N, KAKIUCHIDA H, SATO T, et al. Omniphobic metal surfaces with low contact angle hysteresis and tilt angles[J]. Langmuir, 2018, 34(38):11405-11413.
[66] HOFFMANN F, WOLFF T, MINKO S, et al. Photochemical structuring and fixing of structures in binary polymer brush layers via 2π+2π photodimerization[J]. Journal of Colloid and Interface Science, 2005, 282(2):349-358.
[67] JULTHONGPIPUT D, LIN Y H, TENG J, et al. Y-shaped amphiphilic brushes with switchable micellar surface structures[J]. Journal of the American Chemical Society, 2003, 125(51):15912-15921.
[68] MOTORNOV M, SHEPAROVYCH R, TOKAREV I, et al. Nonwettable thin films from hybrid polymer brushes can be hydrophilic[J]. Langmuir, 2007, 23(1):13-19.
[69] DE VOS K, GIRONES J, POPELKA S, et al. SOI optical microring resonator with poly (ethylene glycol) polymer brush for label-free biosensor applications[J]. Biosensors and Bioelectronics, 2009, 24(8):2528-2533.
[70] CROOKS R M. Patterning of hyperbranched polymer films[J]. ChemPhysChem, 2001, 2(11):644-654.
[71] MONTAGNE F, POLESEL-MARIS J, PUGIN R, et al. Poly (N-isopropylacrylamide) thin films densely grafted onto gold surface:Preparation, characterization, and dynamic AFM study of temperature-induced chain conformational changes[J]. Langmuir, 2009, 25(2):983-991.
[72] 李斌, 于波, 周峰. 表面引发聚合新进展及应用[J]. 高分子学报, 2016(10):1312-1329. LI B, YU B, ZHOU F. Recent advances and applications in surface-initiated polymer brushes[J]. Acta Polymerica Sinica, 2016(10):1312-1329. (in Chinese)
[73] MONGA D, GUO Z Q, SHAN L, et al. Quasi-liquid surfaces for sustainable high-performance steam condensation[J]. ACS Applied Materials & Interfaces, 2022, 14(11):13932-13941.
[74] ZHANG L, GUO Z Q, SARMA J, et al. Passive removal of highly wetting liquids and ice on quasi-liquid surfaces[J]. ACS Applied Materials & Interfaces, 2020, 12(17):20084-20095.
[75] PYUN J, KOWALEWSKI T, MATYJASZEWSKI K. Synthesis of polymer brushes using atom transfer radical polymerization[J]. Macromolecular Rapid Communications, 2003, 24(18):1043-1059.
[76] ZHU B C, EDMONDSON S. Polydopamine-melanin initiators for Surface-initiated ATRP[J]. Polymer, 2011, 52(10):2141-2149.
[77] CHIERA S, BITTNER C, VOGEL N. Substrate- independent design of liquid-infused slippery surfaces via mussel-inspired chemistry[J]. Advanced Materials Interfaces, 2021, 8(12):2100156.
[78] TAMBUNLERTCHAI S, SRISANG S, NASONGKLA N. Development of antimicrobial coating by later-by-layer dip coating of chlorhexidine-loaded micelles[J]. Journal of Materials Science:Materials in Medicine, 2017, 28(6):90.
[79] 佟威, 熊党生. 仿生超疏水表面的发展及其应用研究进展[J]. 无机材料学报, 2019, 34(11):1133-1144. TONG W, XIONG D S. Bioinspired superhydrophobic materials:Progress and functional application[J]. Journal of Inorganic Materials, 2019, 34(11):1133-1144. (in Chinese)
[80] LIU M M, HOU Y Y, LI J, et al. Transparent slippery liquid-infused nanoparticulate coatings[J]. Chemical Engineering Journal, 2018, 337:462-470.
[81] LI Q, GUO Z G. Lubricant-infused slippery surfaces:Facile fabrication, unique liquid repellence and antireflective properties[J]. Journal of Colloid and Interface Science, 2019, 536:507-515.
[82] WANG Y L, DU X, WANG X, et al. Patterned liquid-infused nanocoating integrating a sensitive bacterial sensing ability to an antibacterial surface[J]. ACS Applied Materials & Interfaces, 2022, 14(20):23129-23138.
[83] WARE C S, SMITH-PALMER T, PEPPOU-CHAPMANS, et al. Marine antifouling behavior of lubricant-infused nanowrinkled polymeric surfaces[J]. ACS Applied Materials & Interfaces, 2018, 10(4):4173-4182.
[84] GUAN J H, RUIZ-GUTIÉRREZ É, XU B B, et al. Drop transport and positioning on lubricant-impregnated surfaces[J]. Soft Matter, 2017, 13(18):3404-3410.
[85] GERALDI N R, GUAN J H, DODD L E, et al. Double-sided slippery liquid-infused porous materials using conformable mesh[J]. Scientific Reports, 2019, 9(1):13280.
[86] SOLOMON B R, KHALIL K S, VARANASI K K. Drag reduction using lubricant-impregnated surfaces in viscous laminar flow[J]. Langmuir, 2014, 30(36):10970-10976.
[87] LI H, FENG X L, PENG Y J, et al. Durable lubricant-infused coating on a magnesium alloy substrate with anti-biofouling and anti-corrosion properties and excellent thermally assisted healing ability[J]. Nanoscale, 2020, 12(14):7700-7711.
[88] ŁATKA L, PAWŁOWSKI L, WINNICKI M, et al. Review of functionally graded thermal sprayed coatings[J]. Applied Sciences, 2020, 10(15):5153.
[89] ZHANG C Y, CHU Z H, WEI F S, et al. Optimizing process and the properties of the sprayed Fe-based metallic glassy coating by plasma spraying[J]. Surface and Coatings Technology, 2017, 319:1-5.
[90] LIANG Y Z, LI C Y, WANG P, et al. Fabrication of a robust slippery liquid infused porous surface on Q235 carbon steel for inhibiting microbiologically influenced corrosion[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2021, 631:127696.
[91] AGARWAL H, BREINING W M, LYNN D M. Continuous fabrication of slippery liquid-infused coatings on rolls of flexible materials[J]. ACS Applied Polymer Materials, 2022, 4(2):787-795.
[92] WANG D H, GUO Z G. A bioinspired lubricant infused surface with transparency, hot liquid boiling resistance and long-term stability for food applications[J]. New Journal of Chemistry, 2020, 44(11):4529-4537.
[93] LU J X, WU S L, LIANG Z H, et al. Brushable lubricant-infused porous coating with enhanced stability by one-step phase separation[J]. ACS Applied Materials & Interfaces, 2021, 13(19):23134-23141.
[94] KOIVULUOTO H, HARTIKAINEN E, NIEMELÄ- ANTTONEN H. Thermally sprayed coatings:Novel surface engineering strategy towards icephobic solutions[J]. Materials, 2020, 13(6):1434.
[95] KHAMMAS R, KOIVULUOTO H. Durable icephobic slippery liquid-infused porous surfaces (SLIPS) using flame-and cold-spraying[J]. Sustainability, 2022, 14(14):8422.
[96] DONADEI V, KOIVULUOTO H, SARLIN E, et al. Icephobic behaviour and thermal stability of flame-sprayed polyethylene coating:The effect of process parameters[J]. Journal of Thermal Spray Technology, 2020, 29(1):241-254.
[97] DARBAND G B, ALIOFKHAZRAEI M, KHORSAND S, et al. Science and engineering of superhydrophobic surfaces:Review of corrosion resistance, chemical and mechanical stability[J]. Arabian Journal of Chemistry, 2020, 13(1):1763-1802.
[98] KIM P, WONG T S, ALVARENGA J, et al. Liquid-infused nanostructured surfaces with extreme anti-ice and anti-frost performance[J]. ACS Nano, 2012, 6(8):6569-6577.
[99] BOKOV D, TURKI J A, CHUPRADIT S, et al. Nanomaterial by sol-gel method:Synthesis and application[J]. Advances in Materials Science and Engineering, 2021, 2021:5102014.[WX)] [WX(3KG0,25*2]
[100] WEI C Q, ZHANG G F, ZHANG Q H, et al. Silicone oil-infused slippery surfaces based on sol-gel process-induced nanocomposite coatings:A facile approach to highly stable bioinspired surface for biofouling resistance[J]. ACS Applied Materials & Interfaces, 2016, 8(50):34810-34819.
[101] LI R S, ZHAO L Z, YAO A F, et al. Design of lubricant-infused surfaces based on mussel-inspired nanosilica coatings:Solving adhesion by pre-adhesion[J]. Langmuir, 2021, 37(36):10708-10719.
[102] ZHU Y, HE Y, YANG D Q, et al. A facile method to prepare mechanically durable super slippery polytetrafluoroethylene coatings[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2018, 556:99-105.
[103] ZHU X T, LU J W, LI X M, et al. Simple way to a slippery lubricant impregnated coating with ultrastability and self-replenishment property[J]. Industrial & Engineering Chemistry Research, 2019, 58(19):8148-8153.
[104] ZHU L, XUE J, WANG Y Y, et al. Ice-phobic coatings based on silicon-oil-infused polydimethylsiloxane[J]. ACS Applied Materials & Interfaces, 2013, 5(10):4053-4062.
[105] COUSTET M, IRIGOYEN J, GARCIA T A, et al. Layer-by-layer assembly of polymersomes and polyelectrolytes on planar surfaces and microsized colloidal particles[J]. Journal of Colloid and Interface Science, 2014, 421:132-140.
[106] SUNNY S, VOGEL N, HOWELL C, et al. Lubricant-infused nanoparticulate coatings assembled by layer-by-layer deposition[J]. Advanced Functional Materials, 2014, 24(42):6658-6667.
[107] MANABE K, NISHIZAWA S, KYUNG K H, et al. Optical phenomena and antifrosting property on biomimetics slippery fluid-infused antireflective films via layer-by-layer comparison with superhydrophobic and antireflective films[J]. ACS Applied Materials & Interfaces, 2014, 6(16):13985-13993.
[108] MANNA U, LYNN D M. Fabrication of liquid-infused surfaces using reactive polymer multilayers:Principles for manipulating the behaviors and mobilities of aqueous fluids on slippery liquid interfaces[J]. Advanced Materials, 2015, 27(19):3007-3012.
[109] ZHU G H, CHO S H, ZHANG H, et al. Slippery liquid-infused porous surfaces (SLIPS) using layer-by-layer polyelectrolyte assembly in organic solvent[J]. Langmuir, 2018, 34(16):4722-4731.
[110] WU J X, ZHANG B W, WANG B J, et al. The fabrication of multifunctional SLIPS films by electrospinning[J]. ChemNanoMat, 2017, 3(12):869-873.
[111] WANG Y F, QIAN B T, LAI C L, et al. Flexible slippery surface to manipulate droplet coalescence and sliding, and its practicability in wind-resistant water collection[J]. ACS Applied Materials & Interfaces, 2017, 9(29):24428-24432.
[112] AGARWAL H, QUINN L J, WALTER S C, et al. Slippery antifouling polymer coatings fabricated entirely from biodegradable and biocompatible components[J]. ACS Applied Materials & Interfaces, 2022, 14(15):17940-17949.
[113] SU C L, CHANG J J, TANG K X, et al. Novel three-dimensional superhydrophobic and strength-enhanced electrospun membranes for long-term membrane distillation[J]. Separation and Purification Technology, 2017, 178:279-287.
[114] TIAN X L, BAI H, ZHENG Y M, et al. Bio-inspired heterostructured bead-on-string fibers that respond to environmental wetting[J]. Advanced Functional Materials, 2011, 21(8):1398-1402.
[115] DAYAL P, LIU J, KUMAR S, et al. Experimental and theoretical investigations of porous structure formation in electrospun fibers[J]. Macromolecules, 2007, 40(21):7689-7694.
[116] [JP+2]KOOMBHONGSE S, LIU W X, RENEKER D H. Flat[JP+3]polymer ribbons and other shapes by electrospinning[J]. Journal of Polymer Science Part B:Polymer Physics, 2001, 39(21):2598-2606.
[117] ZHAO Y, CAO X Y, JIANG L. Bio-mimic multichannel microtubes by a facile method[J]. Journal of the American Chemical Society, 2007, 129(4):764-765.
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