Synthesis and characterisation of ultra-porous material for oil spill treatment based on natural cellulose extracted from office paper wastes
Keywords:
Aerogel, natural cellulose, oil spill treatment, solvent recycling
Abstract
Aero-cellulose with porosity over 90% and absolute buoyancy was successfully produced from the highly pure cellulose fibres extracted from office paper wastes. Solvent recycling method was applied to reduce the time and increase the technical and economic efficiency of hydrophobisation of the as-produced hydrophilic aero-cellulose product. The obtained material exhibits super hydrophobicity in various oil-water mixtures. Every gram of the aero-cellulose material obtained from 3 hours of ETMS modification could restore up to 30 – 45 grams of water-free oil and could be re-used.
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3. Ola Abdelwahab, Samir M.Nasr, Walaa M.Thabet. Palm fibers and modified palm fibers adsorbents for different oils. Alexandria Engineering Journal. 2017; 56(4): p. 749 - 755.
4. Dan Li, Fu Zhen Zhu, Jing Yi Li, Ping Na, Na Wang. Preparation and characterization of cellulose fibers from corn straw as natural oil sorbents. Industrial & Engineering Chemistry Research. 2103; 52(1): p. 516 - 524.
5. Đào Trọng Hiền, Ngô Quốc Bưu, Huỳnh Thị Hà, Nguyễn Hoài Châu. Nghiên cứu điều chế vật liệu dialdehyt xenlulo bằng phương pháp oxy hóa periodat và các tính chất cơ lí của nó. Tạp chí Khoa học và Công nghệ. 2011; 49(1): p. 63 - 72.
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8. Runjun Lin, Ang Li, Tingting Zheng, Lingbin Lu, Yang Cao. Hydrophobic and flexible cellulose aerogel as an efficient, green and reusable oil sorbent. RSC Advances. 2015; 5: p. 82027 - 82033.
9. Son T.Nguyen, Jingduo Feng, Nhat T.Le, Ai T.T.Le, Nguyen Hoang, Vincent B.C.Tan, Hai M.Duong. Cellulose aerogel from paper waste for crude oil spill cleaning. Industrial & Engineering Chemistry Research. 2013; 52(51): p. 18386 - 18391.
10. Hoàng Thị Phương. Nghiên cứu tổng hợp và biến tính vật liệu nanosilica ứng dụng cho quá trình thu hồi dầu. Luận án Tiến sĩ Kỹ thuật hóa học. Đại học Bách khoa Hà Nội. 2018.
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14. Test Method T222 om-02 (R2011). Acid-insoluble lignin in wood and pulp. Technical Association of the Pulp and Paper Industry. 2011.
15. ASTM D-3906-03(2013). Standard test method for determination of relative X-ray diffraction intensities of faujasite-type zeolite-containing materials.
16. ASTM F 726-06. Standard test method for sorbent performance of adsorbents.
17. ASTM D1141 - 98(2013). Standard practice for the preparation of substitute ocean water.
18. ASTM D 6304-04. Standard test method for determination of water in petroleum products, lubricating oils, and additives by coulometric karl fischer titration.
19. Dieter Klemm, Brigitte Heublein, Hans-Peter Fink, Andreas Bohn. Cellulose: fascinating biopolymer and sustainable raw material. Angewandle Chemie International Edition. 2005; 44(22): p. 3358 - 3393.
20. Yasuhiro Takahashi, Hideki Matsunaga. Crystal structure of native cellulose. Macromolecules. 1991; 24(13): p. 3968 - 3969.
21. Noriko Hayashi, Junji Sugiyama, Takeshi Okano, Mitsuro Ishihara. Selective degradation of the cellulose Iαcomponent in Cladophora cellulose with Trichoderma viride cellulase. Carbohydrate Research. 1998; 305(1): p. 109 - 116.
22. Haiping Yang, Rong Yan, Hanping Chen, Dong Ho Lee, Chuguang Zheng. Characteristics of hemicellulose, cellulose and lignin pyrolysis. Fuel. 2007; 86(12-13): p. 1781 - 1788.
23. Eduardo Robles, Iñaki Urruzola, Jalel Labidi, Luis Serrano. Surface-modified nano-cellulose as reinforcement in poly (lactic acid) to conform new composites. Industrial Crops and Products. 2015; 71: p. 44 - 53.
24. Weixia Qing, Yong Wang, Youyou Wang, Dongbao Zhao, Xiuhua Liu, Jinhua Zhua. The modified nanocrystalline cellulose for hydrophobic drug delivery. Applied Surface Science. 2016; 366: p. 404 - 409.
25. Jingquan Han, Chengjun Zhou, Yiqiang Wu, Fangyang Liu, Qinglin Wu. Self-Assembling behavior
of cellulose nanoparticles during freeze drying: Effect of suspension concentration, particle size, crystal structure, and surface charge. Biomacromolecules. 2013; 14(5): p. 1529 - 1540.
26. Hanieh Kargarzadeh, Rasha M. Sheltami, Ishak Ahmad, Ibrahim Abdullah, Alain Dufresne. Cellulose nanocrystal: A promising toughening agent for unsaturated polyester nanocomposite. Polymer. 2015; 56: p. 346 - 357.
27. Hanieh Kargarzadeh, Ishak Ahmad, Ibrahim Abdullah, Alain Dufresne, Siti Yasmine Zainudin, Rasha M.Sheltami. Effects of hydrolysis conditions on the morphology, crystallinity, and thermal stability of cellulose nanocrystals extracted from kenaf bast fibers. Cellulose. 2012; 19(3): p. 855 - 866.
28. Rosica Mincheva, Latifah Jasmani, Thomas Josse, Yoann Paint, Jena-Marie Raquez, Pascal Gerbaux, Samuel Eyley, Wim Thielemans, Philippe Dubois. Binary mixed homopolymer brushes tethered to cellulose nanocrystals: a step towards compatibilized polyester blends. Biomacromolecules. 2016; 17(9): p. 3048 - 3059.
29. Daniele Oliveira Castro, Julien Bras, Alessandro Gandini, Naceur Belgacem. Surface grafting of cellulose nanocrystals with natural antimicrobial rosin mixture using a green process. Carbohydrate Polymers. 2016; 137: p. 1 - 8.
30. Daniel Loof, Matthias Hiller, Hartmut Oschkinat, Katharina Koschek. Quantitative and qualitative analysis of surface modified cellulose utilizing TGA-MS. Materials. 2016; 9(6).
31. Juan Rubio, Maria Alejandra Mazo, Araceli MártinIlana, Aitana Tamayo. FT-IR study of the hydrolysis and condensation of 3-(2-amino-ethylamino)propyl-trimethoxy silane. Boletín de la Sociedad Española de Cerámica y Vidrio. 2018; (57): p. 160 - 168.
Published
2019-03-29
How to Cite
Vo Nguyen Xuan Phuong, Luong Ngoc Thuy, Le Phuc Nguyen, & Nguyen Huu Luong. (2019). Synthesis and characterisation of ultra-porous material for oil spill treatment based on natural cellulose extracted from office paper wastes. Petrovietnam Journal, 3, 52-61. https://doi.org/10.25073/petrovietnam journal.v3i0.248
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