| POLYMERS AND POLYMER MATRIX COMPOSITES |
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| Research Progress in Modification of Textiles Materials by Plasma Technology |
| CHEN Fangchun, ZHANG Tonghua, XU Mengting, LI Zhi
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| College of Textile and Apparel, Southwest University, Chongqing 400700, China |
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Abstract Modification is to improve the inherent properties of textile materials or endow them with new properties. The methods for modification mainly include biological modification, chemical modification and physical modification. Plasma technology is a typical technology of physical modification, which is mainly based on plasma generated by ionization to achieve various modification purposes. In recent years, plasma technology has become a very active and rapidly developing research field, and it plays an important role in the surface modification of textile materials.
Compared with other modification methods, the plasma technology has better maneuverability with less chemicals and pollution. The plasma perform modification on the surface of materials instead of affecting their internal structure. The researches on the modification of textile materials based on plasma technology mainly focuses on these four aspects: (1) cleaning effect; (2) surface morphology modification; (3) the introduction of free radicals; (4) plasma polymerization.
Low temperature plasma is a widely used plasma technology for modifying textile materials since it has minimum negative effect on modified materials. The plasma technology improves wettability, friction resistance, biocompatibility and dyeability of textile materials through plasma etching activation, free radical modification and polymer coating. Moreover, it can endow the textile materials with antibacterial property, self-cleaning effect and even self-healing functions, so as to enhance the application value of textiles and expand its application scope.
This paper briefly introduces the classifications of plasma technology and summarizes the development of plasma technology. And this particularly focuses on the application of plasma technology in textile materials and elaborates the research progress on the modification of textile fiber, fabric and fibrous membrane relating to plasma technology in detail. Finally, based on this review, the research prospects of plasma technology for textile material modification are proposed.
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Published: 03 November 2021
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| Fund:Basic Science and Frontier Technology Research Project of Chongqing, China (cstc2017jcyjAX0087), Innovation Funded Projects of Innovation Program in 2019 of Chongqing, China (cx2019090)and Key Projects of Basic Scientific Research Business Expenses in Central Universities of China(XDJK2018B015). |
About author:: Fangchun Chen, master, her research direction is smart textiles.
Zhi Li, Ph.D, associate professor, his research directions are functional fiber and biomedical materials. |
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1 Di J H. Chinese Journal of Liquid Crystals and Displays, 1989(6),45(in Chinese).
邸建华.发光快报,1989(6),45.
2 Zhang X K. China High Tech Enterprise, 2012(3),94(in Chinese).
张兴科.中国高新技术企业,2012(3),94.
3 Anthony L P, Zheng Y X. Scientific & Technology Book Review, 2015(9),14(in Chinese).
Anthony L P,郑耀昕.国外科技新书评介,2015(9),14.
4 Song H, Wang B W, Xu G H. Chemical Industry and Engineering, 2007, 24(4),356(in Chinese).
宋华,王保伟,许根慧.化学工业与工程,2007,24(4),356.
5 Shen J J. China Strategic Emerging Industry, 2018, 172(40),157(in Chinese).
沈锴钧.中国战略新兴产业,2018,172(40),157.
6 Wang L J. Journal of Yibin University, 2009, 9(6),41(in Chinese).
王利娟.宜宾学院学报,2009,9(6),41.
7 Huang H N. Low Carbon World, 2015(19), 9(in Chinese).
黄虎宁.低碳世界,2015(19),9.
8 Mao M M. Study on the treatment of printing and dyeing sludge by thermal plasma gasification technology. Master's Thesis, Zhejiang Univer-sity, 2017(in Chinese).
毛梦梅.热等离子体气化技术处理印染污泥的研究.硕士学位论文,浙江大学,2017.
9 Zhang Y, Liu Z W, Tan X H, et al. Chinese Brewing, 2019(1),20(in Chinese).
张晔,刘志伟,谭兴和,等.中国酿造,2019(1),20.
10 Nestler K, Böttger-Hiller F, Adamitzki W, et al. Procedia CIRP, 2016, 42,503.
11 Bónová L, Zahoranová A, Kováčik D, et al. Applied Surface Science, 2015, 331,79.
12 Franck C M. IEEE Transactions on Power Delivery, 2011,26(2),998.
13 Seeger M. Plasma Chemistry and Plasma Processing, 2015, 35(3),527.
14 Mariotti D, Belmonte T, Benedikt J, et al. Plasma Processes and Polymers, 2016, 13(1),70.
15 Rubin M B. Chemical & Pharmaceutical Bulletin, 2001, 26(1), 40.
16 Yang W, Rong M Z. Electrotechnical Journal, 2000(3), 3(in Chinese).
杨武,荣命哲.电工技术杂志,2000(3),3.
17 Nestler K, Böttger-Hiller F, Adamitzki W, et al. Procedia CIRP, 2016, 42,503.
18 Moisan M, Barbeau J, Moreau S, et al. International journal of Pharmaceutics, 2001, 226(1-2),1.
19 Moisan M, Levif P, Séguin J, et al. Journal of Physics D: Applied Phy-sics, 2014, 47(28),285404.
20 Keidar M, Shashurin A, Volotskova O, et al. Physics of Plasmas, 2013, 20(5),057101.
21 Schlegel J, Köritzer J, Boxhammer V. Clinical Plasma Medicine, 2013, 1(2),2.
22 Ehlbeck J, Schnabel U, Andrasch M, et al. Contributions to Plasma Physics, 2015, 55(10),753.
23 Ekezie F G C, Sun D W, Cheng J H. Trends in Food Science & Technology, 2017, 69,46.
24 Randeniya L K,de Groot G J J B. Plasma Processes and Polymers, 2015, 12,608.
25 Zille A,Oliveira F R, Souto A P. Plasma Processes and Polymers, 2014,12(2), 98.
26 Iris Kippler,Rolf-Dieter Hund,Chokri Cherif.AU-TEX Research Journal, 2014,14(1),34.
27 Liu T. Advanced Textile Technology, 2013(1),66(in Chinese).
刘涛.现代纺织技术,2013(1),66.
28 Peng H K, Zheng G, Wang R. Fibers and Polymers, 2015, 16(12),2538.
29 Peng H K, Zheng G, Wang R,et al. RSC Advances, 2015, 5,78172.
30 Atyabi S M, Sharifi F, Irani S, et al. Cell Biochemistry and Biophysics, 2016, 74(2),181.
31 Tverdokhlebov S I, Bolbasov E N, Antonova L V, et al. Materials Letters, 2016,171,87.
32 Wen Y, Meng X, Liu J, et al. High Performance Polymers, 2016, 29(9), 1083.
33 Sun X, Bu J, Liu W, et al. Science and Engineering of Composite Mate-rials, 2017,24(4),477.
34 Jia C, Chen P, Wang Q, et al. Polymer Composites, 2016,37(2), 620.
35 Chang Q X, Zhao H J, He R Q. Surface and Interface Analysis, 2017,49(8), 750.
36 Eung-seok Lee,Choong-hyun Lee,Yoon-Soo Chun, et al. Composites Part B: Engineering, 2017,116, 451.
37 Sahebalzamani M, Biazar E, Shahrezaei M, et al. International Journal of Polymeric Materials and Polymeric Biomaterials, 2015, 64(3),149.
38 Lu Z, Hu W, Xie F, et al. Journal of Applied Polymer Science, 2017,134(34),45215.
39 Vrabič Brodnjak, Jesih Adolf,Gregor-Svetec Diana,et al. Coatings, 2018,8(4), 133.
40 Chang Y, Sun T, Fan C, et al. Composite Interfaces, 2018, 25(3),1.
41 Zhang Y, Ma X, Cai P N. Cotton Textile Technology, 2014, 42(2),32(in Chinese).
张莹,马新安,蔡普宁.棉纺织技术,2014, 42(2),32.
42 Xi W W, Jian H, Yun L. E-Journal of Chemistry, 2012, 9(3),1581.
43 Moosburger-Will J, Lachner E, Löffler M, et al. Applied Surface Science, 2018, 453,141.
44 Xiao Y, Lu W. Journal of Materials Chemistry A, 2016,4, 18164.
45 Song J B, Yuan Q P. Bioresources, 2015,10(3), 5820.
46 Xu D, Liu B, Zhang G, et al. High Performance Polymers, 2016,128(4),411.
47 Moosburger-Will J, Bauer M, Schubert F, et al. Surface and Coatings Technology, 2017, 311,223.
48 Hande Yavuz, Grégory Girard, Jinbo Bai, et al. Thin Solid Films, 2016,616, 220.
49 Song C L, Zhang Z T, Zhao W G, et al. Chemical Reaction Engineering and Technology, 2010, 26(2),112(in Chinese).
宋春莲,张芝涛,赵文光,等.化学反应工程与工艺,2010,26(2),112.
50 Xie P, Shu Q, Wang H W. Journal of Anhui Normal University(Natural Science), 2011,34(6),546(in Chinese).
解鹏,舒情,王红卫.安徽师范大学学报(自然科学版)2011,34(6),546.
51 Cheng W, Yang Y, Yin B, et al. China Plastics Industry, 2019,47(8), 133(in Chinese).
程旺,杨屹,尹波,等.塑料工业,2019,47(8),133.
52 Jamaliniya S, Samei N, Shahidi S. Journal of the Textile Institute, 2019,110(5), 647.
53 Zhang C M. Applied Surface Science, 2018,434, 198.
54 Zhang C M, Guo F S, Li H Y, et al. Applied Surface Science, 2019,490, 157.
55 Zhang R, Wang A. Journal of Cleaner Production, 2015, 87,961.
56 Shahidi S, Moazzenchi B. Fibers Polymer, 2019,20,1658.
57 Peng S J. Study on the influence of atmospheric pressure plasma treatment on the solubility of PVA film and the desizing effect of cotton fabric.Master's Thesis, Donghua University, China,2009(in Chinese).
彭淑静.常压等离子体处理对 PVA 薄膜溶解性能和棉织物退浆效果的影响研究.硕士学位论文,东华大学,2009.
58 Kan C W, Lam Y L. Fibers and Polymers, 2015, 16(8),1705.
59 Li Y, Moyo S, Ding Z, et al. Industrial Crops and Products, 2013, 51,299.
60 Zhang M, Pang J, Bao W, et al. Applied Surface Science, 2017, 419,16.
61 Špitalsky Z, Rástočná Illová D, Žigo O, et al. Fibers Polymer, 2019,20,1649.
62 Kan C W, Man W S. Polymers, 2018, 10(3), 233.
63 Zanini S, Grimoldi E, Citterio A, et al. Applied Surface Science, 2015, 349,235.
64 Zanini S, Citterio A, Leonardi G, et al. Applied Surface Science, 2017, 427,90.
65 Li S, Jinjin D. Applied Surface Science, 2007, 253(11),5051.
66 Li Y Q, Liu J Q. Journal of Textile Research, 2006, 27(6),8(in Chinese).
李永强,刘今强.纺织学报,2006,27(6),8.
67 Zanini S, Freti S, Citterio A, et al. Surface and Coatings Technology, 2016,292, 155.
68 Rani K V, Chandwani N, Kikani P, et al. The Journal of The Textile Institute, 2018,109(3), 368.
69 Fauland G, Constantin F, Gaffar H, et al. Journal of Applied Polymer Science, 2015, 132(3),41294.
70 Zhang C, Zhao M, Wang L, et al. Applied Surface Science, 2017, 400,304.
71 Li H Y, Fu J J, Wang H B, et al. Materials Repots, 2018, 32(4),626(in Chinese).
李宏英,傅佳佳,王鸿博,等.材料导报,2018,32(4),626.
72 Zhou C E, Kan C W. Applied Surface Science, 2015, 328,410.
73 Yu J, Pang Z, Zhang J, et al. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2018,548, 117.
74 Cerny P, Bartos P, Olsan P, et al. Current Applied Physics, 2019, 19(2),128.
75 Zhang Y, Li Y, Shao J, et al. Surface & Coatings Technology, 2015,276,16.
76 Zhang Y, Li Y Q, Shao J Z, et al. Journal of Textile Research, 2016(7), 99(in Chinese).
张严,李永强,邵建中,等.纺织学报,2016(7),99.
77 Li Y Q, Zhang Y, Zou C, et al. Applied Surface Science, 2015,357, 2327.
78 Yan X, Li J, Yi L. Materials Letters, 2017, 208(1),46.
79 Irfan M, Polonskyi O, Hinz A, et al. Cellulose, 2019,26, 8877.
80 Zhang Y F, Jia Q X, Wang X, et al. IOP Conference Series: Materials Science and Engineering, 2015, 87,012053.
81 Tsafack M J, Levalois-Grützmacher J. Surface & Coatings Technology, 2006, 200(11),3503.
82 Zhao R J,Wang W S, Zhu F F, et al. Desalination and Water Treatment, 2014, 56(9),1.
83 Correia D M, Ribeiro C, Botelho G, et al. Applied Surface Science, 2016, 371,74.
84 Jiang R, Chen H F. IOP Conference Series: Earth and Environmental Science, 2018,108, 022024.
85 Correia D M, Ribeiro C, Sencadas V, et al. Progress in Organic Coa-tings, 2015, 85,151.
86 Volkov V V,Ibragimov R G,Sh Abdullin I, et al. Journal of Physics: Conference Series, 2016, 751,012028.
87 Li M S, Zhao Z P, Wang M X. Applied Surface Science, 2016, 386(15),187.
88 Vasilkin D P, Shikova T G, Titov V A, et al. Journal of Physics: Confe-rence Series, 2017, 789,012068.
89 Li G H, Shi Y, Fu Z F, et al. Chemical Industry and Engineering Progress, 2013,32(9),2166(in Chinese).
李贵合,石艳,付志峰,等.化工进展, 2013,32(9), 2166.
90 Zheng Z, Wang W, Huang X, et al. Plasma Processes & Polymers, 2018,15,e1700122. |
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2021, Vol. 35 
