纤维素基超疏水材料的研究进展

doi:10.3969/j.issn.0253-2417.2016.06.018

Abstract

Abstract: The superhydrophobicity of material surface is depended on the combination of low surface-energy substances and micro/nano rough surface structure. This plays an important role in adsorption, self-cleaning materials, corrosion resistance, and low dragging coatings fields. Cellulose is a renewable biomaterial with good mechanical property, flexibility and permeability. The physical and chemical modification on cellulose can change the surface property to achieve desired superhydrophobicity, which significantly extends the application of cellulose. In this review, the research developments of constructing superhydrophobic cellulose-based materials were summarized. The dipping, spraying, grafting, vapor deposition and hydrothermal method for the modification of cotton, filter paper and microspheres were described in detail.

Key words: cellulose, micro/nano structure, superhydrophobicity

CLC Number:

TQ35

WU Long-hui, LU Sheng-chang, LIN Xin-xing, XIAO He, WU Hui, HUANG Liu-lian, CHEN Li-hui. Research Progress in Superhydrophobic Cellulose-based Materials[J]. Chemistry and Industry of Forest Products, 2016, 36(6): 119-126.

References

[1] 张俐娜.天然高分子改性材料及应用[M].北京:化学工业出版社,2006. ZHANG Li-na.Modified Natural Polymer Materials and Applications[M].Beijing:Chemical Industry Press,2006.
[2] DAOUD W A,XIN J H,ZHANG Y H.Surface functionalization of cellulose fibers with titanium dioxide nanoparticles and their combined bactericidal activities[J].Surface Science,2005,599(1/2/3):69-75.
[3] ANDRESEN M,JOHANSSON L S,TANEM B S,et al.Properties and characterization of hydrophobized microfibrillated cellulose[J].Cellulose,2006,13(6):665-677.
[4] HASANI M,CRANSTON E D,WESTMAN G,et al.Cationic surface functionalization of cellulose nanocrystals[J].Soft Matter,2008,4(11):2238-2244.
[5] HABIBI Y,GOFFIN A L,SCHILTZ N,et al.Bionanocomposites based on poly(ε-caprolactone)-grafted cellulose nanocrystals by ring-opening polymerization[J].Journal of Materials Chemistry,2008,18:5002-5010.
[6] FUKUZUMI H,SAITO T,WATA T,et al.Transparent and high gas barrier films of cellulose nanofibers prepared by tempo-mediated oxidation[J].Biomacromolecules,2009,10(1):162-165.
[7] CHANG Chun-yu,DUAN Be,ZHANG Li-na.Fabrication and characterization of novel macroporous cellulose-alginate hydrogels[J].Polymer,2009,50(23):5467-5473.
[8] CETIN N S,TINGAUT P,OEZMEN N,et al.Acetylation of cellulose nanowhiskers with vinyl acetate under moderate conditions[J].Macromolecular Bioscience,2009,9(10):997-1003.
[9] ZHOU X,LIN X,WHITE K L,et al.Effect of the degree of substitution on the hydrophobicity of acetylated cellulose for production of liquid marbles[J].Cellulose,2016,23(1):811-821.
[10] O'Sullivan A.Cellulose:The structure slowly unravels[J].Cellulose,1997,4(3):173-207.
[11] GAO Xue-feng,JIANG Lei.Water-repellent legs of water striders[J].Nature,2004,432(7013):36.
[12] CHEN W,FADEEV A Y,HSIEH M C,et al.Ultrahydrophobic and ultralyophobic surfaces:Some comments and examples[J].Langmuir,1999,15(10):3395-3399.
[13] NOSONOVSKY M.Materials science:Slippery when wetted[J].Nature,2011,477(7365):412-413.
[14] 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.
[15] 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.
[16] MA W,WU H,HIGAKI Y,et al.Anon-sticky' superhydrophobic surface prepared by self-assembly of fluoroalkyl phosphonic acid on a hierarchically micro/nanostructured alumina gel film[J].Chemical Communications,2012,48(54):6824-6826.
[17] YOUNG T.An essay on the cohesion of fluids[J].Philosophical Transactions of the Royal Society of London,1805,95:65-87.
[18] WENZEL R N.Resistance of solid surfaces to wetting by water[J].Industrial & Engineering Chemistry,1936,28(8):988-994.
[19] CASSIE A,BAXTEr S.Wettability of porous surfaces[J].Transactions of the Faraday Society,1944,40:546-551.
[20] WANG Hong-xia,FANG Jian,CHENG Tong,et al.One-step coating of fluoro-containing silica nanoparticles for universal generation of surface superhydrophobicity[J].Chemical Communications,2008,(7):877-879.
[21] JIN Cheng-feng,JIANG Yu-feng,NIU Tao,et al.Cellulose-based material with amphiphobicity to inhibit bacterial adhesion by surface modification[J].Journal of Materials Chemistry,2012,22(25):12562-12567.
[22] ZHOU Hua,WANG Hong-xia,NIU Hai-tao,et al.Fluoroalkyl silane modified silicone rubber/nanoparticle composite:A super durable,robust superhydrophobic fabric coating[J].Advanced Materials,2012,24(18):2409-2412.
[23] ARBATAN T,ZHANG L,FANG X Y,et al.Cellulose nanofibers as binder for fabrication of superhydrophobic paper[J].Chemical Engineering Journal,2012,210:74-79.
[24] LI Sheng-hai,ZHANG Suo-bo,Wang Xian-hong.Fabrication of superhydrophobic cellulose-based materials through a solution-immersion process[J].Langmuir,2008,24(10):5585-5590.
[25] ZHOU Xiao-yan,ZHANG Zhao-zhu,XU Xiong-hui,et al.Robust and durable superhydrophobic cotton fabrics for oil/water separation[J].ACS Applied Materials & Interfaces,2013,5(15):7208-7214.
[26] GAO Zheng-xin,ZHAI Xiang-lin,LIU Feng,et al.Fabrication of TiO₂/EP super-hydrophobic thin film on filter paper surface[J].Carbohydrate Polymers,2015,128:24-31.
[27] LIU Feng,MA Miao-lian,ZANG De-li,et al.Fabrication of superhydrophobic/superoleophilic cotton for application in the field of water/oil separation[J].Carbohydrate Polymers,2014,103:480-487.
[28] FENG Xiao-juan,SHI Yan-long,LIU Jia,et al.Fabrication of filter paper with tunable wettability and its application in oil-water separation[J].Journal of Sol-Gel Science and Technology,2015,76(1):129-137.
[29] LIU Ming-hua,DENG Yun,ZHAN Huai-yu,et al.Adsorption and desorption of copper(Ⅱ) from solutions on new spherical cellulose adsorbent[J].Journal of Applied Polymer Science,2002,84(3):478-485.
[30] LIN Xin-xing,MA Wei,WU Hui,et al.Superhydrophobic magnetic poly(DOPAm-co-PFOEA)/Fe3O4/cellulose microspheres for stable liquid marbles[J].Chemical Communications,2016,52(9):1895-1898.
[31] AUSSILLOUS P,QUERE D.Liquid marbles[J].Nature,2001,411(6840):924-927.
[32] WU H,WATANABE H,MA W,et al.Robust liquid marbles stabilized with surface-modified halloysite nanotubes[J].Langmuir,2013,29(48):14971-14975.
[33] KARAPANAGIOTIS I,GROSU D,ASLANIDOU D,et al.Facile method to prepare superhydrophobic and water repellent cellulosic paper[J].Journal of Nanomaterials,2015.Article ID:219013.
[34] OGIHARA H,XIE J,OKAGAKI J,et al.Simple method for preparing superhydrophobic paper:Spray-deposited hydrophobic silica nanoparticle coatings exhibit high water-repellency and transparency[J].Langmuir,2012,28(10):4605-4608.
[35] BAYER I S,BISWAS A,Ellialtioglu G.Fabrication of super water repellent silver flake/copolymer blend films and their potential as smart fabrics[J].Polymer Composites,2011,32(4):576-585.
[36] ZHANG Wei,LU Peng,QIAN Li-ying,et al.Fabrication of superhydrophobic paper surface via wax mixture coating[J].Chemical Engineering Journal,2014,250:431-436.
[37] ZHANG Wei,XIAO Hui-ning,QIAN Li-ying.Enhanced water vapour barrier and grease resistance of paper bilayer-coated with chitosan and beeswax[J].Carbohydrate Polymers,2014,101:401-406.
[38] ZHANG Yong-lai,WANG Jian-nan,HE Yan,et al.Solvothermal synthesis of nanoporous polymer chalk for painting superhydrophobic surfaces[J].Langmuir,2011,27(20):12585-12590.
[39] DENG Bo,CAI Ren,YU Yang,et al.Laundering durability of superhydrophobic cotton fabric[J].Advanced Materials,2010,22(48):5473-5477.
[40] MATYJASZEWSKI K,TSAREVSKY N V.Macromolecular engineering by atom transfer radical polymerization[J].Journal of the American Chemical Society,2014,136(18):6513-6533.
[41] PERRIER S,TAKOLPUCKDEE P,WESTWOOD J,et al.Versatile chain transfer agents for reversible addition fragmentation chain transfer (RAFT) polymerization to synthesize functional polymeric architectures[J].Macromolecules,2004,37(8):2709-2717.
[42] ROY D,GUTHRIE J T,PERRIER S.Graft polymerization:Grafting poly(styrene) from cellulose via reversible addition fragmentation chain transfer (RAFT) polymerization[J].Macromolecules,2005,38(25):10363-10372.
[43] Carlmark A,MALMSTRÖM E.Atom transfer radical polymerization from cellulose fibers at ambient temperature[J].Journal of the American Chemical Society,2002,124(6):900-901.
[44] HANSSON S,ÖSTMARK E,CARLMARK A,et al.ARGET ATRP for versatile grafting of cellulose using various monomers[J].ACS Applied Materials & Interfaces,2009,1(11):2651-2659.
[45] NYSTROM D,LINDQVIST J,OSTMARK E,et al.Superhydrophobic and self-cleaning bio-fiber surfaces via ATRP and subsequent postfunctionalization[J].Acs Applied Materials & Interfaces,2009,1(4):816-823.
[46] NYSTROM D,LINDQVIST J,OSTMARK E,et al.Superhydrophobic bio-fibre surfaces via tailored grafting architecture[J].Chemical Communications,2006,(34):3594-3596.
[47] XIAO M,LI S,CHANKLIN W,et al.Surface-initiated atom transfer radical polymerization of butyl acrylate on cellulose microfibrils[J].Carbohydrate Polymers,2011,83(2):512-519.
[48] LIU Xiao-yan,CHEN Jing,SUN Ping,et al.Grafting modification of ramie fibers with poly(2,2,2-trifluoroethyl methacrylate) via reversible addition-fragmentation chain transfer (RAFT) polymerization in supercritical carbon dioxide[J].Reactive and Functional Polymers,2010,70(12):972-979.
[49] YI Jie,CHEN Jing,LIU Zhao-tie,et al.Grafting of polystyrene and poly (p-chlorostyrene) from the surface of ramie fiber via RAFT polymerization[J].Journal of Applied Polymer Science,2010,117(6):3551-3557.
[50] CHEN Jing,YI Jie,SUN Ping,et al.Grafting from ramie fiber with poly(MMA) or poly(MA) via reversible addition-fragmentation chain transfer polymerization[J].Cellulose,2009,16(6):1133-1145.
[51] BALU B,BREEDVELD V,HESS D W.Fabrication of ‘roll-off’ and ‘sticky’ superhydrophobic cellulose surfaces via plasma processing[J].Langmuir,2008,24(9):4785-4790.
[52] CHO S C,HONG Y C,CHO S G,et al.Surface modification of polyimide films,filter papers,and cotton clothes by HMDSO/toluene plasma at low pressure and its wetability[J].Current Applied Physics,2009,9(6):1223-1226.
[53] CORTESE B,CASCHERA D,FEDERICI F,et al.Superhydrophobic fabrics for oil-water separation through a diamond like carbon (DLC) coating[J].Journal of Materials Chemistry A,2014,2(19):6781-6789.
[54] JIN H,KETTUNEN M,LAIHO A,et al.Superhydrophobic and superoleophobic nanocellulose aerogel membranes as bioinspired cargo carriers on water and oil[J].Langmuir,2011,27(5):1930-1934.
[55] CERVIN N T,AULIN C,LARSSON P T,et al.Ultra porous nanocellulose aerogels as separation medium for mixtures of oil/water liquids[J].Cellulose,2012,19(2):401-410.
[56] ARTUS G R,JUNG S,ZIMMERMANN J,et al.Silicone nanofilaments and their application as superhydrophobic coatings[J].Advanced Materials,2006,18(20):2758-2762.
[57] ZIMMERMANN J,REIFLER F A,FORTUNATO G,et al.A simple,one-step approach to durable and robust superhydrophobic textiles[J].Advanced Functional Materials,2008,18(22):3662-3669.

Research Progress in Superhydrophobic Cellulose-based Materials

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