Materials Reports  2021, Vol. 35 Issue (z2): 550-553 |
| POLYMERS AND POLYMER MATRIX COMPOSITES |
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| Research and Development of Biomimetic Antifouling Strategies |
| ZHANG Kai, GUI Taijiang, WU Lianfeng, CONG Weiwei, LYU Zhao
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| State Key Laboratory of Marine Coating, Marine Chemical Research Institute Co., Ltd, Qingdao 266071, China |
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Abstract Surface of artificial facilities such as ships, oil production platforms and aquaculture cages are easily absorbed by abundant marine fouling organisms which accelerate surface corrosion and equipment aging,seriously endangering the stability and safety of marine facilities. Antifouling performance of coatings should fulfil lots of requirements including long-term stability, high effectiveness, and eco-friendliness for the sake of being applied on a large scale in practice. Organic tin based antifouling paints showing long-term and stable inhibition effect to various of marine fouling organisms developed rapidly in the middle of 20th century, but they had been banned for the damage to the marine ecological environment. Biomimetic antifouling coatings have become a significant research direction due to their excellent antifouling and environmental-friendly perfor-mance. In this review, antifouling characteristics, antifouling mechanism and efficacy of different strategies are briefly introduced, and the research progress and development trend of biomimetic antifouling strategies are summarized.
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Published: 09 December 2021
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| Fund:This work was financially supported by the National Natural Science Foundation of China (U2006219). |
| About author:: Kai Zhang received his B.E. degree in chemistry from Sun Yat-Sen University in 2012 and received his Ph.D. degree in polymer chemistry and physics from Sun Yat-Sen University, in 2017. Now he is an engineer at the research center of the Marine Chemical Research Institute Co., Ltd., and a postdoctoral fellow at the State Key Laboratory of Marine Coating. His research has focused on environmentally friendly marine antifouling coating. |
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1 Michael P S, John A B, Eric R H, et al. Biofouling, 2011, 27(1), 87.
2 Sathianeson S, Mohammad Abdulaziz B A, Abdulmohsin A A S. Electronic Journal of Biotechnology, 2016, 21, 26.
3 Katherine A D, John A L, Emma L J. Marine Pollution Bulletin, 2011, 62, 453.
4 Wenjing Y, Konn-Gee N, En-Tang K, et al. Progress in Polymer Science, 2014, 39(5), 1017.
5 Marlène L, André M, Christine B. Chemical Review, 2012, 112, 4347.
6 Ioannis M, Usaid A. Coatings, 2020, 10, 653.
7 Mohamed S S, Mohamed A S, El-Safty S A, et al. Progress in Materials Science, 2017, 87, 1.
8 Michael P S. Biofouling, 2007, 23, 331.
9 Yunqing G, Songwei Y, Jiegang M, et al. Marterials, 2020, 13(2), 444.
10 Gregory D B, Bhushan B. Philosophical Transactions of The Royal Society A, 2012, 370, 2381.
11 Chelsea M K, Anthony B B. Annual Review of Materials Research, 2012, 42(1), 211.
12 Joana R A, Vitor V. Biotechnology Advances, 2015, 33(3-4), 343.
13 Herbert W, Marvin T. Science, 1981, 212(4498), 1038.
14 Rosaria C, Frank V B, Pagliaro M. ACS Sustainable Chemistry & Engineering, 2015, 3, 559.
15 Maria S, Julian A W, Yves B, et al. Environmental Microbiology, 2013, 15(11), 2879.
16 Axel R, Sören S, Hans Jürgen K, et al. Physical Chemistry Chemical Physical, 2010, 12(17), 4275.
17 Chelsea M M, Scott P C, Anthony B B. Materials Today, 2010, 13, 36.
18 Luanne H S, William C J, Paul S. Nature Reviews Microbiology, 2004, 2(2), 95.
19 James A C, Maureen E C. Nature Communication, 2011, 2, 244.
20 Liqun X, Koon-Gee N, En-Tang K. Progress in Polymer Science, 2018, 87, 165.
21 Emanuele O, Robert G C, Erik H R, et al. Langmuir, 2001, 17, 5605.
22 Frank P, Robin S, Goran M N, et al. Biofouling, 2011, 27(6), 579.
23 Eleanor H, Jane F, Daniel J, et al. Molecules, 2001, 6, 130.
24 Tamilselvan M, AljaČ, Matej B, et al. ACS Biomaterials Science & Engineering, 2019, 5, 5825.
25 Jun Z, Wei L, Zhiqiang Y, et al. Mairne Drugs, 2019, 17, 101.
26 Kang F, Chunhua N, Liangmin Y, et al. Colloids & Surfaces B Biointerfaces, 2019, 184, 110518.
27 Hui L, Siyu C, Jiaying G, et al. International Biodeterioration & Biodegradation, 2018, 127, 170.
28 Almeida Joana R, Moreira J, Pereira D, et al. Science of the Total Environment, 2018, 643, 98.
29 Florent T, Celine M, Sylvain P, et al. Marine Drugs, 2020, 18(5), 272.
30 Li W, Liangmin Y, Cunguo L. Journal of Ocean University of China, 2019, 18, 1139.
31 Maria S, Julian A W, Paul S, et al. Philosophical Transactions of The Royal Society A, 2010, 368, 4729.
32 Atieh H, Ranga P. Langmuir, 2014, 30(14), 4183.
33 Ruijian J, Lingwan H, Lingjie S, et al. Chemical Engineering Journal, 2020, 398, 125609.
34 Michelle L C, Thomas G E, Adam W F, et al. Biofouling, 2006, 22(1-2), 11.
35 Xia P, Guangji L, Hanlu H. Biology Open, 2016, 5, 389.
36 Tak-Sing W, Hoon-Kang S, Sindy K Y T, et al. Nature, 2011, 477, 433.
37 Huaxia Z, Qiangqiang S, Xu D, et al. Advanced Materials, 2018, 30(29),
38 Sheeana G, Claire H, Aoife C P, et al. Journal of Materials Chemistry B, 2016, 4(34), 5747.
39 Agata Maria B, Stan M, Rubayn Gohzhi R, et al. ACS Applied Material & Interfaces, 2017, 9(20), 17508.
40 Ailin G, Yehai Y, Tiantian L, et al. Marterials Letters, 2019, 237, 240.
41 Xinyu C, Michala E. P, Florian W, et al. Advanced Functional Mate-rials, 2010, 20(12), 1984. |
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