纤维素气凝胶的制备与应用进展
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摘要
对纤维素气凝胶的分类以及制备方法进行了总结,综述了纤维素气凝胶在隔热领域、电学、吸附、催化等领域的应用进展,并对纤维素气凝胶的制备改性进行了探讨,最后对纤维素气凝胶未来发展趋势进行了展望。
Classification and preparation methods for cellulose aerogel are summarized.The application progress of cellulose aerogel in heat insulation,electricity,adsorption and catalysis fields is reviewed.Preparation and modification of cellulose aerogel are also discussed.Finally,the future development trend of cellulose aerogel is prospected.
Classification and preparation methods for cellulose aerogel are summarized.The application progress of cellulose aerogel in heat insulation,electricity,adsorption and catalysis fields is reviewed.Preparation and modification of cellulose aerogel are also discussed.Finally,the future development trend of cellulose aerogel is prospected.
引文
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[25]Sun F,Liu W,Dong Z,et al. Underwater superoleophobicity cellulose nanofibril aerogel through regioselective sulfonation for oil/water separation[J].Chemical Engineering Journal,2017,330:774-782.
[26]He Z,Zhang X,Batchelor W.Cellulose nanofiber aerogel filter with tuneable pore structure for oil/water separation and recovery[J].RSC Advances,2016,6(26):21435-21438.
[27]Bo S,Ren W,Lei C,et al.Flexible and porous cellulose aerogels/zeolitic imidazolate framework(ZIF-8)hybrids for adsorption removal of Cr(Ⅳ)from water[J]. Journal of Solid State Chemistry,2018,262:135-141.
[28]Zhang J,Zhang J.Advanced functional materials based on cellulose[J].Acta Polym Sin,2010,12:1376-1398.
[29]Ren W,Gao J,Lei C,et al. Recyclable metal-organic framework/cellulose aerogels for activating peroxymonosulfate to degrade organic pollutants[J]. Chemical Engineering Journal,2018,349:766-774.
[30]Su X,Liao Q,Liu L,et al.Cu2O nanoparticle-functionalized cellulose-based aerogel as high-performance visible-light photocatalyst[J].Cellulose,2017,24(2):1017-1029.
[2]Ulker Z,Erkey C.An emerging platform for drug delivery:Aerogel based systems[J]. Journal of Controlled Release,2014,177:51-63.
[3]Stergar J,Maver U.Review of aerogel-based materials in biomedical applications[J].Journal of Sol-Gel Science and Technology,2016,77(3):738-752.
[4]Long L Y,Weng Y X,Wang Y Z.Cellulose aerogels:Synthesis,applications,and prospects[J].Polymers,2018,10(6):623-650.
[5]Wu Z Y,Li C,Liang H W,et al. Ultralight,flexible,and fireresistant carbon nanofiber aerogels from bacterial cellulose[J].Angewandte Chemie,2013,125(10):2997-3001.
[6]Sai H,Xing L,Xiang J,et al.Flexible aerogels with interpenetrating network structure of bacterial cellulose-silica composite from sodium silicate precursor via freeze drying process[J]. RSC Advances,2014,4(57):30453-30461.
[7]Gan S,Zakaria S,Chen R S,et al.Autohydrolysis processing as an alternative to enhance cellulose solubility and preparation of its regenerated bio-based materials[J]. Materials Chemistry and Physics,2017,192:181-189.
[8]Cui S,Wang X,Zhang X,et al.Preparation of magnetic MnFe2O4-Cellulose aerogel composite and its kinetics and thermodynamics of Cu(Ⅱ)adsorption[J].Cellulose,2018,25(1):735-751.
[9]Ren F,Li Z,Tan W Z,et al.Facile preparation of 3D regenerated cellulose/graphene oxide composite aerogel with high-efficiency adsorption towards methylene blue[J]. Journal of Colloid and Interface Science,2018,532:58-67.
[10]Sescousse R,Gavillon R,Budtova T.Aerocellulose from cellulose-ionic liquid solutions:Preparation,properties and comparison with cellulose-NaOH and cellulose-NMMO routes[J]. Carbohydrate polymers,2011,83(4):1766-1774.
[11]Nechyporchuk O,Belgacem M N,Bras J. Production of cellulose nanofibrils:A review of recent advances[J]. Industrial Crops and Products,2016,93:2-25.
[12]Liu H,Geng B,Chen Y,et al. Review on the aerogel-type oil sorbents derived from nanocellulose[J].ACS Sustainable Chemistry&Engineering,2016,5(1):49-66.
[13]de Oliveira P B,Godinho M,Zattera A J.Oils sorption on hydrophobic nanocellulose aerogel obtained from the wood furniture industry waste[J].Cellulose,2018,25(5):3105-3119.
[14]Cao Y,Jiang Y,Song Y,et al.Combined bleaching and hydrolysis for isolation of cellulose nanofibrils from waste sackcloth[J].Carbohydrate Polymers,2015,131:152-158.
[15]Chen K,Xue D. In-situ electrochemical route to aerogel electrode materials of graphene and hexagonal CeO2[J]. Journal of Colloid and Interface Science,2015,446:77-83.
[16]Rees A,Powell L C,Chinga-Carrasco G,et al.3D bioprinting of carboxymethylated-periodate oxidized nanocellulose constructs for wound dressing applications[J]. BioMed Research International,2015,2015:1-7.
[17]Korhonen J T,Hiekkataipale P,Malm J,et al. Inorganic hollow nanotube aerogels by atomic layer deposition onto native nanocellulose templates[J].ACS Nano,2011,5(3):1967-1974.
[18]Tan C,Fung B M,Newman J K,et al. Organic aerogels with very high impact strength[J]. Advanced Materials,2001,13(9):644-646.
[19]Lin R,Li A,Lu L,et al.Preparation of bulk sodium carboxymethyl cellulose aerogels with tunable morphology[J]. Carbohydrate Polymers,2015,118:126-132.
[20]Huang H D,Liu C Y,Zhou D,et al.Cellulose composite aerogel for highly efficient electromagnetic interference shielding[J].Journal of Materials Chemistry A,2015,3(9):4983-4991.
[21]Wan Y J,Zhu P L,Yu S H,et al.Ultralight,super-elastic and volume-preserving cellulose fiber/graphene aerogel for highperformance electromagnetic interference shielding[J]. Carbon,2017,115:629-639.
[22]Feng J,Nguyen S T,Fan Z,et al.Advanced fabrication and oil absorption properties of super-hydrophobic recycled cellulose aerogels[J].Chemical Engineering Journal,2015,270:168-175.
[23]Zhai T,Zheng Q,Cai Z,et al. Synthesis of polyvinyl alcohol/cellulose nanofibril hybrid aerogel microspheres and their use as oil/solvent superabsorbents[J].Carbohydrate Polymers,2016,148:300-308.
[24]Liao Q,Su X,Zhu W,et al.Flexible and durable cellulose aerogels for highly effective oil/water separation[J].RSC Advances,2016,6(68):63773-63781.
[25]Sun F,Liu W,Dong Z,et al. Underwater superoleophobicity cellulose nanofibril aerogel through regioselective sulfonation for oil/water separation[J].Chemical Engineering Journal,2017,330:774-782.
[26]He Z,Zhang X,Batchelor W.Cellulose nanofiber aerogel filter with tuneable pore structure for oil/water separation and recovery[J].RSC Advances,2016,6(26):21435-21438.
[27]Bo S,Ren W,Lei C,et al.Flexible and porous cellulose aerogels/zeolitic imidazolate framework(ZIF-8)hybrids for adsorption removal of Cr(Ⅳ)from water[J]. Journal of Solid State Chemistry,2018,262:135-141.
[28]Zhang J,Zhang J.Advanced functional materials based on cellulose[J].Acta Polym Sin,2010,12:1376-1398.
[29]Ren W,Gao J,Lei C,et al. Recyclable metal-organic framework/cellulose aerogels for activating peroxymonosulfate to degrade organic pollutants[J]. Chemical Engineering Journal,2018,349:766-774.
[30]Su X,Liao Q,Liu L,et al.Cu2O nanoparticle-functionalized cellulose-based aerogel as high-performance visible-light photocatalyst[J].Cellulose,2017,24(2):1017-1029.
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