Superhydrophobic modification of cellulose film through light curing polyfluoro resin in situ

Springer Science and Business Media LLC - Tập 25 - Trang 1617-1623 - 2018
Yuehan Wu1, Zhuojia Qian1,2, Yujie Lei1,2, Wei Li1, Xia Wu1, Xiaogang Luo3, Yan Li1, Bin Li1, Shilin Liu1,2,4
1College of Food Science and Technology, Huazhong Agricultural University, Wuhan, China
2Beijing Engineering and Technology Research Center of Food Additives, Beijing Technology and Business University, Beijing, China
3Key Laboratory of Green Chemical Process of Ministry of Education, School of Chemical Engineering and Pharmacy, Wuhan Institute of Technology, Wuhan, China
4Jiangsu Province Biomass Energy and Materials Laboratory, Nanjing, China

Tóm tắt

Cellulose-based film has a poor water vapor barrier property, which limits its applications in food packaging. The hydrophobic modification of cellulose materials has attracted increasing interests. In this work, UV curable polyfluoro resin was incorporated into the cellulose matrix for superhydrophobic modification of the cellulose matrix. Results showed that the loaded polyfluoro resin had an obvious influence on the composites’ microstructure, the thermal stability of the composites changed slightly with the incorporation of polyfluoro resin, and the transmittance of the composites containing the resin with high content of 14.68% could be kept to 50% at 550 nm wavelength. Furthermore, the surface properties of the composites could be changed from hydrophobic to superhydrophobic by increasing the polyfluoro resin content. Moreover, UV-initiated polymerization was used to modify the cellulose matrix, the process was green and facile, which showing potential for cellulose matrix modification.

Tài liệu tham khảo

Abbas R, Khereby M, Sadik W, El Demerdash A (2015) Fabrication of durable and cost effective superhydrophobic cotton textiles via simple one step process. Cellulose 22(1):887–896 Althues H, Henle A, Kaskel S (2007) Functional inorganic nanofillers for transparent polymers. Chem Soc Rev 36(9):1454–1465 Ayadi F, Bayer IS, Fragouli D, Liakos I, Cingolani R, Athanassiou A (2013) Mechanical reinforcement and water repellency induced to cellulose sheets by a polymer treatment. Cellulose 20:1501–1509 Barnette AL, Bradley LC, Veres BD, Schreiner EP, Park YB, Park J, Park S, Kim SH (2011) Selective detection of crystalline cellulose in plant cell walls with sum-frequency-generation (SFG) vibration spectroscopy. Biomacromolecules 12(7):2434–2439 da Silva R, Sierakowski MR, Bassani HP, Zawadzki SF, Pirich CL, Ono L, de Freitas RA (2016) Hydrophilicity improvement of mercerized bacterial cellulose films by polyethylene glycol graft. Int J Biol Macromol 86:599–605 Feng J, Nguyen ST, Fan Z, Duong HM (2015) Advanced fabrication and oil absorption properties of super-hydrophobic recycled cellulose aerogels. Chem Eng J 270:168–175 Ferrer A, Pal L, Hubbe M (2017) Nanocellulose in packaging: advances in barrier layer technologies. Ind Crops Prod 95:574–582 French AD (2014) Idealized powder diffraction patterns for cellulose polymorphs. Cellulose 21:885–896 He M, Xu M, Zhang L (2013) Controllable stearic acid crystal induced high hydrophobicity on cellulose film surface. ACS Appl Mater Interfaces 5:585–591 Hu Z, Berry RM, Pelton R, Cranston ED (2017) One-pot water-based hydrophobic surface modification of cellulose nanocrystals using plant polyphenols. ACS Sustain Chem Eng 5(6):5018–5026 Li W, Wu Y, Liang W, Li B, Liu S (2014) Reduction of the water wettability of cellulose film through controlled heterogeneous modification. ACS Appl Mater Interfaces 6(8):5726–5734 Li W, Luo X, Song R, Zhu Y, Li B, Liu S (2016) Porous cellulose microgel particle: a fascinating host for the encapsulation, protection, and delivery of lactobacillus plantarum. J Agric Food Chem 64(17):3430–3436 Li W, Zhu Y, Ye F, Li B, Luo X, Liu S (2017) Probiotics in cellulose houses: enhanced viability and targeted delivery of Lactobacillus plantarum. Food Hydrocoll 62:66–72 Liji Sobhana S, Zhang X, Kesavan L, Liias P, Fardim P (2017) Layered double hydroxide interfaced stearic acid—Cellulose fibres: a new class of super-hydrophobic hybrid materials. Colloids Surf A Physicochem Eng Asp 522:416–424 Miao C, Hamad W (2013) Cellulose reinforced polymer composites and nanocomposites: a critical review. Cellulose 20(5):2221–2262 Miao J, Yu Y, Jiang Z, Zhang L (2016) One-pot preparation of hydrophobic cellulose nanocrystals in an ionic liquid. Cellulose 23(2):1209–1219 Morgan JLW, Strumillo J, Zimmer J (2013) Crystallographic snapshot of cellulose synthesis and membrane translocation. Nature 493(7431):181–186 Omura T, Imagawa K, Kono K, Suzuki T, Minami H (2016) Encapsulation of either hydrophilic or hydrophobic substances in spongy cellulose particles. ACS Appl Mater Interfaces 9(1):944–949 Osong SH, Norgren S, Engstrand P (2016) Processing of wood-based microfibrillated cellulose and nanofibrillated cellulose, and applications relating to papermaking: a review. Cellulose 23(1):93–123 Pan Y, Xiao H, Song Z (2013) Hydrophobic modification of cellulose fibres by cationicmodified polyacrylate latex with core–shell structure. Cellulose 20:485–494 Rull-Barrull J, d’Halluin M, Le Grognec E, Felpin F-X (2016) Chemically-modified cellulose paper as smart sensor device for colorimetric and optical detection of hydrogen sulfate in water. Chem Commun 52(12):2525–2528 Simmons TJ, Mortimer JC, Bernardinelli OD, Pöppler AC, Brown SP, Dupree R, Dupree P (2016) Folding of xylan onto cellulose fibrils in plant cell walls revealed by solid-state NMR. Nat Commun 7:13902 Song T, Tanpichai S, Oksman K (2016) Cross-linked polyvinyl alcohol (PVA) foams reinforced with cellulose nanocrystals (CNCs). Cellulose 23(3):1925–1938 Suhas V, Carrott P, Singh R, Chaudhary M, Kushwaha S (2016) Cellulose: a review as natural, modified and activated carbon adsorbent: biomass, bioenergy, biowastes, conversion technologies, biotransformations, production technologies. Bioresour Technol 216:1066–1076 Tang CY, Liu HQ (2008) Cellulose nanofiber reinforced poly(vinyl alcohol) composite film with high visible light transmittance. Compos Part A 39(10):1638–1643 Torres S, Navia R, Campbell Murdy R, Cooke P, Misra M, Mohanty AK (2015) Green composites from residual microalgae biomass and poly (butylene adipate-co-terephthalate): processing and plasticization. ACS Sustain Chem Eng 3(4):614–624 Wang X, Xu S, Tan Y, Du J, Wang J (2016) Synthesis and characterization of a porous and hydrophobic cellulose-based composite for efficient and fast oil–water separation. Carbohydr Polym 140:188–194 Wu Y, Luo X, Li W, Song R, Li J, Li Y, Li B, Liu S (2016) Green and biodegradable composite films with novel antimicrobial performance based on cellulose. Food Chem 197:250–256 Yang Q, Saito T, Isogai A (2012) Facile fabrication of transparent cellulose films with high water repellency and gas barrier properties. Cellulose 19:1913–1921 Zhao M, Kuga S, Wu M, Huang Y (2016) Hydrophobic nanocoating of cellulose by solventless mechanical milling. Green Chem 18(10):3006–3012 Zhu Y, Luo X, Wu X, Li W, Li B, Lu A, Liu S (2017) Cellulose gel dispersions: fascinating green particles for the stabilization of oil/water Pickering emulsion. Cellulose 24(1):207–217