[1] Cheryan, M., and N. Rajagopalan. "Membrane processing of oily streams. Wastewater treatment and waste reduction." Journal of membrane science 151.1 (1998): 13-28.
[2] Garcıa-Sánchez, A., and E. Alvarez-Ayuso. "Sorption of Zn, Cd and Cr on calcite. Application to purification of industrial wastewaters." Minerals Engineering 15.7 (2002): 539- 547.
[3] Gatsios, Evangelos, John N. Hahladakis, and Evangelos Gidarakos. "Optimization of electrocoagulation (EC) process for the purification of a real industrial wastewater from toxic metals." Journal of Environmental Management 154 (2015): 117-127.
[4] Ani, J. U., et al. "Nephelometric and functional parameters response of coagulation for the purification of industrial wastewater using Detarium microcarpum." Journal of hazardous materials 243 (2012): 59-66.
[5] Anisuddin, S., Al Hashar, N., & Tahseen, S. (2005). PREVENTION OF OIL SPILL POLLUTION IN SEAWATER USING LOCALLY AVAILABLE MATERIALS. Arabian Journal for Science & Engineering (Springer Science & Business Media BV), 30.
[6] Sarbatly, Rosalam, Duduku Krishnaiah, and Zykamilia Kamin. "A review of polymer nanofibres by electrospinning and their application in oil–water separation for cleaning up marine oil spills." Marine pollution bulletin 106.1-2 (2016): 8-16.
[7] Gupta, Raju Kumar, et al. "Oil/water separation techniques: a review of recent progresses and future directions." Journal of Materials Chemistry A 5.31 (2017): 16025-16058.
[8] Liu, Qin, et al. "Recent advances in energy materials by electrospinning." Renewable and Sustainable Energy Reviews 81 (2018): 1825-1858.
[9] Alvarez, Pedro JJ, et al. "Emerging opportunities for nanotechnology to enhance water security." Nature nanotechnology 13.8 (2018): 634-641.
[10] Zhu, Liangliang, et al. "Recent progress in solar-driven interfacial water evaporation: Advanced designs and applications." Nano Energy 57 (2019): 507-518.
[11] Kuang, Yudi, et al. "A high‐performance self‐regenerating solar evaporator for continuous water desalination." Advanced materials 31.23 (2019): 1900498.
[12] Jiang, Kun, et al. "Highly selective oxygen reduction to hydrogen peroxide on transition metal single atom coordination." Nature communications 10.1 (2019): 1-11.
[13] Benito, JoséManuel, et al. "Design and construction of a modular pilot plant for the treatment of oil-containing wastewaters." Desalination 147.1-3 (2002): 5-10.
[14] Husseien, M., et al. "A comprehensive characterization of corn stalk and study of carbonized corn stalk in dye and gas oil sorption." Journal of Analytical and Applied Pyrolysis 86.2 (2009): 360-363.
[15] Fritt-Rasmussen, Janne, Susse Wegeberg, and Kim Gustavson. "Review on burn residues from in situ burning of oil spills in relation to Arctic waters." Water, Air, & Soil Pollution 226.10 (2015): 1-12.
[16] Bullock, Robin J., Robert A. Perkins, and Srijan Aggarwal. "In-situ burning with chemical herders for Arctic oil spill response: Meta-analysis and review." Science of the Total Environment 675 (2019): 705-716.
[17] Lessard, Richard R., and Greg DeMarco. "The significance of oil spill dispersants." Spill Science & Technology Bulletin 6.1 (2000): 59-68.
[18] Chapman, Helen, et al. "The use of chemical dispersants to combat oil spills at sea: A review of practice and research needs in Europe." Marine Pollution Bulletin 54.7 (2007): 827- 838.
[19] Schaflinger, Uwe. "Centrifugal separation of a mixture." Fluid Dynamics Research 6.5-6 (1990): 213.
[20] Wang, Xianfeng, et al. "Electrospun nanofibrous materials: a versatile medium for effective oil/water separation." Materials today 19.7 (2016): 403-414.
[21] SPCC GUIDANCE FOR REGIONAL INSPECTORS, December 16, 2013
[22] Gaaseidnes, Knut, and Joseph Turbeville. "Separation of oil and water in oil spill recovery operations." Pure and applied chemistry 71.1 (1999): 95-101.
[23] Frising, Tom, Christine Noïk, and Christine Dalmazzone. "The liquid/liquid sedimentation process: from droplet coalescence to technologically enhanced water/oil emulsion gravity separators: a review." Journal of dispersion science and technology 27.7 (2006): 1035-1057.
[24] Xu, Jiajie, et al. "In-line and selective phase separation of medium-chain carboxylic acids using membrane electrolysis." Chemical Communications 51.31 (2015): 6847-6850.
[25] Deng, Yuying, et al. "Recent development of super-wettable materials and their applications in oil-water separation." Journal of Cleaner Production 266 (2020): 121624.
[26] Padaki, Mahesh, et al. "Membrane technology enhancement in oil–water separation. A review." Desalination 357 (2015): 197-207.
[27] Gupta, Raju Kumar, et al. "Oil/water separation techniques: a review of recent progresses and future directions." Journal of Materials Chemistry A 5.31 (2017): 16025-16058.
[28] Wei, Yibin, et al. "Specially wettable membranes for oil–water separation." Advanced Materials Interfaces 5.23 (2018): 1800576.
[29] Yue, Xuejie, et al. "Design and fabrication of superwetting fiber-based membranes for oil/water separation applications." Chemical Engineering Journal 364 (2019): 292-309.
[30] Qiu, Lei, Yihan Sun, and Zhiguang Guo. "Designing novel superwetting surfaces for highefficiency oil–water separation: design principles, opportunities, trends and challenges." Journal of Materials Chemistry A 8.33 (2020): 16831-16853.
[31] Deng, Yuying, et al. "Metal-organic framework membranes: Recent development in the synthesis strategies and their application in oil-water separation." Chemical Engineering Journal 405 (2021): 127004.
[32] Rasouli, Seyedabbas, et al. "Superhydrophobic and superoleophilic membranes for oilwater separation application: A comprehensive review." Materials & Design 204 (2021): 109599.
[33] Lin, Xiangde, and Jinkee Hong. "Recent advances in robust superwettable membranes for oil–water separation." Advanced Materials Interfaces 6.12 (2019): 1900126.
[34] Junaidi, Nurul Fattin Diana, et al. "Recent development of graphene oxide-based membranes for oil–water separation: A review." Separation and Purification Technology 258 (2021): 118000.
[35] Ma, Wenjing, et al. "Electrospun fibers for oil–water separation." Rsc Advances 6.16 (2016): 12868-12884.
[36] Ryu, Ji Hyun, Seonki Hong, and Haeshin Lee. "Bio-inspired adhesive catechol-conjugated chitosan for biomedical applications: A mini review." Acta biomaterialia 27 (2015): 101-115.
[37] Marmur, Abraham. "The lotus effect: superhydrophobicity and metastability." Langmuir 20.9 (2004): 3517-3519.
[38] Rahim, Md Arifur, et al. "Phenolic building blocks for the assembly of functional materials." Angewandte Chemie International Edition 58.7 (2019): 1904-1927.
[39] Xu, Li Qun, Koon-Gee Neoh, and En-Tang Kang. "Natural polyphenols as versatile platforms for material engineering and surface functionalization." Progress in Polymer Science 87 (2018): 165-196.
[40] McKittrick, J., et al. "Energy absorbent natural materials and bioinspired design strategies: a review." Materials Science and Engineering: C 30.3 (2010): 331-342.
[41] Chen, Ke, et al. "Binary synergy strengthening and toughening of bio-inspired nacre-like graphene oxide/sodium alginate composite paper." Acs Nano 9.8 (2015): 8165-8175.
[42] San Ha, Ngoc, and Guoxing Lu. "A review of recent research on bio-inspired structures and materials for energy absorption applications." Composites Part B: Engineering 181 (2020): 107496.
[43] Kar, Arpan Kumar. "Bio inspired computing–a review of algorithms and scope of applications." Expert Systems with Applications 59 (2016): 20-32.
[44] Tadepalli, Sirimuvva, et al. "Bio-optics and bio-inspired optical materials." Chemical reviews 117.20 (2017): 12705-12763.
[45] Marmur, Abraham. "The lotus effect: superhydrophobicity and metastability." Langmuir 20.9 (2004): 3517-3519.
[46] Banerjee, Indrani, Ravindra C. Pangule, and Ravi S. Kane. "Antifouling coatings: recent developments in the design of surfaces that prevent fouling by proteins, bacteria, and marine organisms." Advanced materials 23.6 (2011): 690-718.
[47] Parvate, Sumit, Prakhar Dixit, and Sujay Chattopadhyay. "Superhydrophobic surfaces: insights from theory and experiment." The Journal of Physical Chemistry B 124.8 (2020): 1323- 1360.
[48] Wei, David W., et al. "Superhydrophobic modification of cellulose and cotton textiles: Methodologies and applications." Journal of Bioresources and Bioproducts 5.1 (2020): 1-15.
[49] Shi, Feng, et al. "Towards understanding why a superhydrophobic coating is needed by water striders." Advanced Materials 19.17 (2007): 2257-2261.
[50] Wang, Shutao, et al. "Bioinspired surfaces with superwettability: new insight on theory, design, and applications." Chemical reviews 115.16 (2015): 8230-8293.
[51] Darmanin, Thierry, and Frédéric Guittard. "Superhydrophobic and superoleophobic properties in nature." Materials today 18.5 (2015): 273-285.
[52] Ivanova, Elena P., et al. "Antifungal versus antibacterial defence of insect wings." Journal of Colloid and Interface Science 603 (2021): 886-897.
[53] Dizge, Nadir, Evyatar Shaulsky, and Vasiliki Karanikola. "Electrospun cellulose nanofibers for superhydrophobic and oleophobic membranes." Journal of Membrane Science 590 (2019): 117271.
[54] Wang, Chenghong, and Zhiguang Guo. "A comparison between superhydrophobic surfaces (SHS) and slippery liquid-infused porous surfaces (SLIPS) in application." Nanoscale 12.44 (2020): 22398-22424.
[55] Zdziennicka, Anna, et al. "Some remarks on the solid surface tension determination from contact angle measurements." Applied Surface Science 405 (2017): 88-101.
[56] Ross, Sydney, and Paul Becher. "The history of the spreading coefficient." Journal of colloid and interface science 149.2 (1992): 575-579.
[57] Schrader, Malcolm E. "Young-dupre revisited." Langmuir 11.9 (1995): 3585-3589.
[58] Wenzel, Robert N. "Resistance of solid surfaces to wetting by water." Industrial & Engineering Chemistry 28.8 (1936): 988-994.
[59] Cassie, A. B. D., and SJToTFS Baxter. "Wettability of porous surfaces." Transactions of the Faraday society 40 (1944): 546-551.
[60] Feng, Lin, et al. "A super‐hydrophobic and super‐oleophilic coating mesh film for the separation of oil and water." Angewandte Chemie 116.15 (2004): 2046-2048.
[61] Zhou, Xiaoyan, et al. "Robust and durable superhydrophobic cotton fabrics for oil/water separation." ACS applied materials & interfaces 5.15 (2013): 7208-7214.
[62] Xue, Chao-Hua, et al. "Fabrication of superhydrophobic and superoleophilic textiles for oil– water separation." Applied Surface Science 284 (2013): 464-471.
[63] Crick, Colin R., James A. Gibbins, and Ivan P. Parkin. "Superhydrophobic polymer-coated copper-mesh; membranes for highly efficient oil–water separation." Journal of Materials Chemistry A 1.19 (2013): 5943-5948.
[64] Gao, Xin, et al. "Robust superhydrophobic foam: a graphdiyne‐based hierarchical architecture for oil/water separation." Advanced Materials 28.1 (2016): 168-173.
[65] Li, Jian, et al. "Superhydrophobic meshes that can repel hot water and strong corrosive liquids used for efficient gravity-driven oil/water separation." Nanoscale 8.14 (2016): 7638-7645.
[66] Zhou, Cailong, et al. "Nature-inspired strategy toward superhydrophobic fabrics for versatile oil/water separation." ACS applied materials & interfaces 9.10 (2017): 9184-9194.
[67] Zhang, Zhi-hui, et al. "One-step fabrication of robust superhydrophobic and superoleophilic surfaces with self-cleaning and oil/water separation function." Scientific reports 8.1 (2018): 1- 12.
[68] Zhu, Xiaoying, et al. "Effective and low fouling oil/water separation by a novel hollow fiber membrane with both hydrophilic and oleophobic surface properties." Journal of membrane science 466 (2014): 36-44.
[69] Adewunmi, Ahmad A., and Muhammad Shahzad Kamal. "Effect of water/decane ratios and salt on the stability, rheology, and interfacial tension of water/decane emulsions." Energy & Fuels 33.9 (2019): 8456-8462.
[70] Ikhsan, Syarifah Nazirah Wan, et al. "Superwetting materials for hydrophilic-oleophobic membrane in oily wastewater treatment." Journal of Environmental Management 290 (2021): 112565.
[71] Wong, Tak-Sing, et al. "Bioinspired self-repairing slippery surfaces with pressure-stable omniphobicity." Nature 477.7365 (2011): 443-447.
[72] Vogel, Nicolas, et al. "Transparency and damage tolerance of patternable omniphobic lubricated surfaces based on inverse colloidal monolayers." Nature communications 4.1 (2013): 1-10.
[73] Waghmare, Prashant R., Naga Siva Kumar Gunda, and Sushanta K. Mitra. "Under-water superoleophobicity of fish scales." Scientific reports 4.1 (2014): 1-5.
[74] Chen, Chaolang, et al. "Separation mechanism and construction of surfaces with special wettability for oil/water separation." ACS applied materials & interfaces 11.11 (2019): 11006- 11027.
[75] Liu, Mingjie, et al. "Bioinspired design of a superoleophobic and low adhesive water/solid interface." Advanced Materials 21.6 (2009): 665-669.
[76] Wang, Yonghua, et al. "One-step method using laser for large-scale preparation of bionic superhydrophobic & drag-reducing fish-scale surface." Surface and Coatings Technology 409 (2021): 126801.
[77] He, Huaqiang, et al. "Superhydrophilic fish-scale-like CuC2O4 nanosheets wrapped copper mesh with underwater super oil-repellent properties for effective separation of oil-inwater emulsions." Colloids and Surfaces A: Physicochemical and Engineering Aspects 627 (2021): 127133.
[78] Su, Xin, et al. "Design of hierarchical comb hydrophilic polymer brush (HCHPB) surfaces inspired by fish mucus for anti-biofouling." Journal of Materials Chemistry B 7.8 (2019): 1322- 1332.
[79] Yong, Jiale, et al. "A review of femtosecond laser-structured superhydrophobic or underwater superoleophobic porous surfaces/materials for efficient oil/water separation." RSC advances 9.22 (2019): 12470-12495.
[80] Zhao, Siyang, et al. "A robust surface with superhydrophobicity and underwater superoleophobicity for on-demand oil/water separation." Nanoscale 13.36 (2021): 15334- 15342.
[81] Cheng, Zhongjun, et al. "pH-controllable on-demand oil/water separation on the switchable superhydrophobic/superhydrophilic and underwater low-adhesive superoleophobic copper mesh film." Langmuir 31.4 (2015): 1393-1399.
[82] Gou, Xiaodan, et al. "Superhydrophilic and underwater superoleophobic cement-coated mesh for oil/water separation by gravity." Colloids and Surfaces A: Physicochemical and Engineering Aspects 605 (2020): 125338.
[83] Wang, Meng, et al. "Mussel-inspired chitosan modified superhydrophilic and underwater superoleophobic cotton fabric for efficient oil/water separation." Carbohydrate polymers 244 (2020): 116449.
[84] Zeng, Zhi-wei Steven, and Spencer E. Taylor. "Facile preparation of superhydrophobic melamine sponge for efficient underwater oil-water separation." Separation and Purification Technology 247 (2020): 116996.
[85] Kavalenka, M. N., et al. "Wood-based microhaired superhydrophobic and underwater superoleophobic surfaces for oil/water separation." Rsc Advances 4.59 (2014): 31079-31083.
[86] Zeng, Minxiang, et al. "Highly biocompatible, underwater superhydrophilic and multifunctional biopolymer membrane for efficient oil–water separation and aqueous pollutant removal." ACS Sustainable Chemistry & Engineering 6.3 (2018): 3879-3887.
[87] Zhu, Meng, et al. "Robust superhydrophilic and underwater superoleophobic membrane optimized by Cu doping modified metal-organic frameworks for oil-water separation and water purification." Journal of Membrane Science 640 (2021): 119755.
[88] Wang, Jiaqi, et al. "Reversible wettability between underwater superoleophobicity and superhydrophobicity of stainless steel mesh for efficient oil–water separation." ACS omega 6.1 (2020): 77-84.
[89] Widawski, Gilles, Michel Rawiso, and Bernard François. "Self-organized honeycomb morphology of star-polymer polystyrene films." Nature 369.6479 (1994): 387-389.
[90] Yabu, Hiroshi, Kouta Inoue, and Masatsugu Shimomura. "Multiple-periodic structures of self-organized honeycomb-patterned films and polymer nanoparticles hybrids." Colloids and Surfaces A: Physicochemical and Engineering Aspects 284 (2006): 301-304.
[91] Chen, Bihai, Takehiko Wada, and Hiroshi Yabu. "Amphiphilic Perforated Honeycomb Films for Gravimetric Liquid Separation." Advanced Materials Interfaces 9.1 (2022): 2101954.
[92] Yabu, Hiroshi, and Masatsugu Shimomura. "Mesoscale pincushions, microrings, and microdots prepared by heating and peeling of self-organized honeycomb-patterned films deposited on a solid substrate." Langmuir 22.11 (2006): 4992-4997.
[93] Chen, Bihai, Takehiko Wada, and Hiroshi Yabu. "Underwater Bubble and Oil Repellency of Biomimetic Pincushion and Plastron-Like Honeycomb Films." Langmuir 36.23 (2020): 6365- 6369.
[94] Yabu, Hiroshi, et al. "Self-assembled porous templates allow pattern transfer to poly (dimethyl siloxane) sheets through surface wrinkling." Polymer journal 44.6 (2012): 573-578.
[95] Yamazaki, Hidekazu, et al. "Formation and control of line defects caused by tectonics of water droplet arrays during self-organized honeycomb-patterned polymer film formation." Soft Matter 10.16 (2014): 2741-2747.
[96] Yabu, Hiroshi, and Masatsugu Shimomura. "Single-step fabrication of transparent superhydrophobic porous polymer films." Chemistry of materials 17.21 (2005): 5231-5234.
[97] Yabu, Hiroshi, et al. "Superhydrophobic and lipophobic properties of self-organized honeycomb and pincushion structures." Langmuir 21.8 (2005): 3235-3237.
[98] Kamei, Jun, and Hiroshi Yabu. "On‐Demand Liquid Transportation Using Bioinspired Omniphobic Lubricated Surfaces Based on Self‐Organized Honeycomb and Pincushion Films." Advanced Functional Materials 25.27 (2015): 4195-4201.
[99] Kamei, Jun, and Hiroshi Yabu. "One step fabrication of mesh-reinforced hierarchic perforated microporous honeycomb films with tunable filtering property." Soft Matter 13.43 (2017): 7834-7839.
[100] El-Samak, Ali A., et al. "Designing flexible and porous fibrous membranes for oil water separation—A review of recent developments." Polymer Reviews 60.4 (2020): 671-716.
[101] Dunne, R., D. Desai, and R. Sadiku. "A review of the factors that influence sound absorption and the available empirical models for fibrous materials." Acoustics Australia 45.2 (2017): 453-469.
[102] Fan, Tingting, et al. "Robust graphene@ PPS fibrous membrane for harsh environmental oil/water separation and all-weather cleanup of crude oil spill by joule heat and photothermal effect." ACS Applied Materials & Interfaces 13.16 (2021): 19377-19386.
[103] Cheng, Qiaoyun, et al. "Facile fabrication of superhydrophilic membranes consisted of fibrous tunicate cellulose nanocrystals for highly efficient oil/water separation." Journal of Membrane Science 525 (2017): 1-8.
[104] Wang, Antuo, et al. "A tree-grapes-like PTFE fibrous membrane with super-hydrophobic and durable performance for oil/water separation." Separation and Purification Technology 275 (2021): 119165.
[105] Xu, Ying, Baoku Zhu, and Youyi Xu. "A study on formation of regular honeycomb pattern in polysulfone film." Polymer 46.3 (2005): 713-717.
[106] Yin, Ming-Jie, et al. "Precise micropatterning of a porous poly (ionic liquid) via maskless photolithography for high-performance nonenzymatic H2O2 sensing." ACS nano 12.12 (2018): 12551-12557.
[107] Pratiwi, Nuraini Dian, et al. "Fabrication of porous silicon using photolithography and reactive ion etching (RIE)." Materials Today: Proceedings 13 (2019): 92-96.
[108] Lorrain, Nathalie, et al. "Submicron gap reduction of micro-resonator based on porous silica ridge waveguides manufactured by standard photolithographic process." Optical Materials 88 (2019): 210-217.
[109] Hu, Yang, et al. "Surface engineering of spongy bacterial cellulose via constructing crossed groove/column micropattern by low-energy CO2 laser photolithography toward scarfree wound healing." Materials Science and Engineering: C 99 (2019): 333-343.
[110] Li, Tingjie, et al. "Self-detached membranes with well-defined pore size, shape and distribution fabricated by underexposure photolithography." Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena 38.4 (2020): 042601.
[111] Oliveira Jr, Osvaldo N., Luciano Caseli, and Katsuhiko Ariga. "The past and the future of Langmuir and Langmuir–Blodgett films." Chemical Reviews 122.6 (2022): 6459-6513.
[112] Hussain, Syed Arshad, et al. "Unique supramolecular assembly through Langmuir– Blodgett (LB) technique." Heliyon 4.12 (2018): e01038.
[113] Baratto, Camilla, et al. "On the alignment of ZnO nanowires by Langmuir–Blodgett technique for sensing application." Applied Surface Science 528 (2020): 146959.
[114] Chiu, Yu-Cheng, et al. "Highly ordered luminescent microporous films prepared from crystalline conjugated rod-coil diblock copolymers of PF-b-PSA and their superhydrophobic characteristics." Soft Matter 7.19 (2011): 9350-9358.
[115] Patankar, Neelesh A. "Supernucleating surfaces for nucleate boiling and dropwise condensation heat transfer." Soft Matter 6.8 (2010): 1613-1620.
[116] Kharangate, Chirag R., and Issam Mudawar. "Review of computational studies on boiling and condensation." International Journal of Heat and Mass Transfer 108 (2017): 1164-1196.
[117] Beysens, D., et al. "How does dew form?." Phase Transitions 31.1-4 (1991): 219-246.
[118] Fukuhira, Yukako, et al. "Interfacial tension governs the formation of self-organized honeycomb-patterned polymer films." Soft Matter 5.10 (2009): 2037-2041.
[119] Fukuhira, Yukako, et al. "Biodegradable honeycomb-patterned film composed of poly (lactic acid) and dioleoylphosphatidylethanolamine." Biomaterials 27.9 (2006): 1797-1802.
[120] Kawano, Takahito, et al. "Honeycomb-shaped surface topography induces differentiation of human mesenchymal stem cells (hMSCs): Uniform porous polymer scaffolds prepared by the breath figure technique." Biomaterials science 2.1 (2014): 52-56.
[121] Bui, Van-Tien, Seung Hyeon Ko, and Ho-Suk Choi. "A surfactant-free bio-compatible film with a highly ordered honeycomb pattern fabricated via an improved phase separation method." Chemical Communications 50.29 (2014): 3817-3819.
[122] Yabu, Hiroshi, Kouta Inoue, and Masatsugu Shimomura. "Multiple-periodic structures of self-organized honeycomb-patterned films and polymer nanoparticles hybrids." Colloids and Surfaces A: Physicochemical and Engineering Aspects 284 (2006): 301-304.
[123] Kamei, Jun, Hiroya Abe, and Hiroshi Yabu. "Biomimetic bubble-repellent tubes: Microdimple arrays enhance repellency of bubbles inside of tubes." Langmuir 33.2 (2017): 585- 590.
[124] Yong, Jiale, et al. "Bioinspired transparent underwater superoleophobic and anti-oil surfaces." Journal of Materials Chemistry A 3.18 (2015): 9379-9384.
[125] Ruffolo, Silvestro A., et al. "Antifouling coatings for underwater archaeological stone materials." Progress in Organic Coatings 104 (2017): 64-71.
[126] Del Grosso, Chelsey A., et al. "Surface hydration for antifouling and bioadhesion." Chemical Science 11.38 (2020): 10367-10377.
[127] Huo, Jinglan, et al. "Underwater transparent miniature “mechanical hand” based on femtosecond laser-induced controllable oil-adhesive patterned glass for oil droplet manipulation." Langmuir 33.15 (2017): 3659-3665.
[128] Zhou, Cailong, et al. "Superhydrophilic and underwater superoleophobic titania nanowires surface for oil repellency and oil/water separation." Chemical Engineering Journal 301 (2016): 249-256.
[129] Huynh, So Hung, et al. "Plastron-mediated growth of captive bubbles on superhydrophobic surfaces." Langmuir 31.24 (2015): 6695-6703.
[130] Li, Zhe, et al. "A porous superhydrophobic surface with active air plastron control for drag reduction and fluid impalement resistance." Journal of Materials Chemistry A 7.27 (2019): 16387-16396.
[131] Hirai, Yuji, Naoki Yanagi, and Masatsugu Shimomura. "Preparations of the artificial plastron device by self-organized honeycomb-patterned films." e-Journal of Surface Science and Nanotechnology 13 (2015): 90-92.
[132] Lucas, Richard. "Ueber das Zeitgesetz des kapillaren Aufstiegs von Flüssigkeiten." Kolloid-Zeitschrift 23.1 (1918): 15-22.
[133] Washburn, Edward W. "Note on a method of determining the distribution of pore sizes in a porous material." Proceedings of the National Academy of Sciences 7.4 (1921): 115-116.
[134] Zhang, Feng, et al. "Nanowire-haired inorganic membranes with superhydrophilicity and underwater ultralow adhesive superoleophobicity for high-efficiency oil/water separation." Advanced Materials 25.30 (2013): 4192-4198.
[135] Lafuma, Aurélie, and David Quéré. "Superhydrophobic states." Nature materials 2.7 (2003): 457-460.
[136] Finn, Robert. "The contact angle in capillarity." Physics of Fluids 18.4 (2006): 047102.
[137] Chen, Ting, et al. "Smart ZIF-L mesh films with switchable superwettability synthesized via a rapid energy-saving process." Separation and Purification Technology 240 (2020): 116647.
[138] Zhou, Peizhang, et al. "Ultrafast preparation of hydrophobic ZIF-67/copper mesh via electrodeposition and hydrophobization for oil/water separation and dyes adsorption." Separation and Purification Technology 272 (2021): 118871.
[139] Wen, Qiang, et al. "Zeolite-coated mesh film for efficient oil–water separation." Chemical Science 4.2 (2013): 591-595.
[140] Li, Jian, et al. "Underwater superoleophobic palygorskite coated meshes for efficient oil/water separation." Journal of materials chemistry A 3.28 (2015): 14696-14702.
[141] Griffin, William C. "Classification of surface-active agents by" HLB"." J. Soc. Cosmet. Chem. 1 (1949): 311-326.
[142] Qian, Dongliang, et al. "TiO2/sulfonated graphene oxide/Ag nanoparticle membrane: In situ separation and photodegradation of oil/water emulsions." Journal of membrane science 554 (2018): 16-25.
[143] Lin, Yi-Min, and Gregory C. Rutledge. "Separation of oil-in-water emulsions stabilized by different types of surfactants using electrospun fiber membranes." Journal of membrane science 563 (2018): 247-258.
[144] Yang, Hao-Cheng, et al. "Mussel-inspired modification of a polymer membrane for ultrahigh water permeability and oil-in-water emulsion separation." Journal of Materials Chemistry A 2.26 (2014): 10225-10230.