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柔性多孔材料在当今众多前沿科学与技术领域发挥着重要作用, 其表面改性将进一步赋予其多样和优异的表面性能, 拓展其在功能和智能可穿戴等领域的应用. 常压等离子体技术由于低温、低能耗、高效、环保、低成本、不改变材料本体特性、易于实现卷对卷制备等优势, 在应用环境、样品材料选择上展现出良好的适应性, 在低熔点柔性材料大面积低成本表面处理方面具有很好的应用前景和研究价值. 本文综述了近年来常压等离子体柔性多孔材料表面改性的几个实例及在新材料、新能源、环保、生物医学中的应用. 探讨了柔性多孔材料常压等离子体均匀处理所遇到的稳定性及渗透性的问题与挑战. 综述了本课题组在常压等离子体稳定放电、卷对卷常压等离子体多孔介质处理及内部渗透性和均匀性方面的研究工作, 介绍了本课题组在常压等离子体纳米颗粒膜沉积动力学及膜结构调控方面的突破和思路. 常压等离子体柔性多孔介质表面处理技术走向应用仍然存在诸多挑战, 需要结合常压等离子体的放电方式及特性、处理材料的结构及加工特性、等离子体和材料的相互作用等来进行综合考虑, 才能提供合理可行的解决方案.
Flexible porous materials play an important role in frontier science and technology fields. Surface modification will further endow the materials with diverse and excellent surface properties, and expand the scope of their applications in functional and intelligent wearable devices. Atmospheric pressure plasma technology has many advantages in treating the flexible materials, such as low temperature, low energy consumption, high efficiency, friendly environment, low cost, no change in material itself characteristics, suitability for roll-to-roll preparation, etc. Also, it presents good adaptability in applied environment and target materials. All these advantages meet the requirements of large area and low-cost surface modification of flexible porous materials. In this paper, we review several researches of atmospheric pressure plasma surface modification of flexible porous materials used in advanced materials, new energy, environmental protection and biomedicine. The problems and challenges of stability and permeability encountered in uniformly treating the flexible and porous materials by atmospheric pressure plasma are presented. Then, we introduce our research work on atmospheric pressure plasma stable discharge, roll-to-roll coating treatment of permeability and uniformity. Finally, we introduce the breakthrough in and ideas on the deposition kinetics of nanoparticle thin films and their microstructure control by atmospheric pressure plasma. However, there are still many challenges to be overcome in the applications of the methods in current situation. Basic characteristics, discharge modes of atmospheric pressure plasma and the relationships of plasma discharge to structure and property of the various treated materials need to be further explored. It is confirmed that the permeability and uniformity of the atmospheric pressure plasma treatment in flexible porous materials are very important and their in-depth investigations will promote the application of this method—a high efficient, environmentally-friendly and continuous way of realizing functional and intelligent wearable devices in the future. -
Keywords:
- atmospheric pressure plasma /
- flexible porous materials /
- material modification /
- uniformity
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图 1 (a) DCSBD电极系统; (b) 在开放环境下的一次“H”型微放电; (c) 在开放环境下300 W表面等离子体; 不同样品上印刷PLLA纳米颗粒的扫描电子显微镜照片, 其中(d)—(g)分别为(d) 未经处理的PET, (e) 未经处理的PP, (f) 经等离子体处理的PET, (g) 经等离子体处理的PP[8]
Fig. 1. (a) DCSBD electrode system; (b) one H-shaped micro-discharge in ambient air; (c) surface plasma in ambient air at 300 W; scanning electron microscope images of PLLA nanoparticles printed on (d) untreated PET, (e) untreated PP, (f) plasma treated PET, and (g) plasma-treated PP[8].
图 2 未经处理的MFC泡沫与(a)水或(b)煤油的相互作用; 等离子体处理的MFC泡沫(占气隙体积的一部分)与水和煤油在(c) MFC泡沫顶部和(d)底部的相互作用[9]
Fig. 2. Interaction of untreated MFC foam with either (a) water or (b) kerosene. Interaction of plasma-treated MFC foam (taking up a portion of the gas gap volume) with water and kerosene on (c) the top side and (d) the bottom side of the MFC foam[9].
图 4 (a) 常压脉冲放电辅助脉冲调制射频辉光放电电流电压特性; 脉冲放电和射频放电段时间间隔为(b) 40和 (c) 10 μs时, 射频起辉阶段的空间结构分布随延时的变化[35]
Fig. 4. (a) Current voltage characteristics of RF discharge burst with (dash) and without (solid) pulsed discharge in pulse modulated RF APGD; temporal evolution of discharge spatial profile during RF discharge burst ignition with the time interval between pulsed discharge and RF discharge burst of (b) 40 and (c) 10 μs[35].
图 5 氦气20 kV连续放电下, 电势在不同微孔直径大小中的分布 (a) 10 μm; (b) 20 μm; (c) 200 μm, 其中图的横纵坐标为微孔的几何尺寸, 右侧颜色条为电势大小, 单位(V)
Fig. 5. Distributions of the potential for different pore sizes of (a) 10 μm, (b) 20 μm, (c) 200 μm, for a helium discharge sustained at 20 kV.
图 6 柔性微孔介质等离子体沉积模型示意图
Fig. 6. Schematic diagram of plasma deposition model for flexible microporous substrate.
图 9 (a) 50% 占空比时鞘层悬浮颗粒随关闭时间的变化; (b) 不同占空比时纳米颗粒薄膜的粒径分布; 不同占空比时沉积纳米颗粒膜的FE-SEM图像, (c)—(d)图对应的占空比分别为(c) 33%, (d) 50%, (e) 67%[26]
Fig. 9. (a) Motion of sheath trapped particles with 50% duty cycle; (b) particle size distribution of nanoparticle films at different duty cycles; FE-SEM images of deposited nanoparticle films at different duty cycles of (c) 33%, (d) 50%, (e) 67%[26].
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[1] Herbert T (Shishoo R) 2007 Plasma Technologies for Textiles (Cambridge: Woodhead Publ. Ltd) pp79−128
[2] Jelil R A 2015 J. Mater. Sci. 50 5913
Google Scholar
[3] Parida D, Jassal M, Agarwal A K 2012 Plasma Chem. Plasma P. 32 1259
Google Scholar
[4] Lommatzsch U, Pasedag D, Baalmann A, Ellinghorst G, Wagner H E 2007 Plasma Process Polym. 4 S1041
Google Scholar
[5] Elabid A E A, Zhang J, Shi J, Guo Y, Ding K, Zhang J 2016 Appl. Surf. Sci. 375 26
Google Scholar
[6] Armenise V, Fanelli F, Milella A, D'Accolti L, Uricchio A, Fracassi F 2020 Surf. Interfaces 20 100600
Google Scholar
[7] Zhu J, Chen J, Luo Y, Sun S, Qin L, Xu H, Zhang P, Zhang W, Tian W, Sun Z 2019 Energy Storage Mater. 23 539
Google Scholar
[8] Ivanova T V, Krumpolec R, Homola T, Musin E, Baier G, Landfester K, Cameron D C, Černák M 2017 Plasma Process Polym. 14 1600231
Google Scholar
[9] Meunier L F, Profili J, Babaei S, Asadollahi S, Sarkissian A, Dorris A, Beck S, Naudé N, Stafford L 2020 Plasma Process Polym. 18 2000158
Google Scholar
[10] Chien H H, Liao C Y, Hao Y C, Hsu C C, Cheng I C, Yu I S, Chen J Z 2018 Electrochim. Acta 260 391
Google Scholar
[11] [12] Talemi P, Delaigue M, Murphy P, Fabretto M 2015 ACS Appl. Mater. Interfaces 7 8465
Google Scholar
[13] Wang T, Wang X, Yang B, Chen X, Liu J 2017 J. Electrochem. Soc. 164 D282
Google Scholar
[14] Zhu S, Gao Y, Hu B, Li J, Su J, Fan Z, Zhou J 2013 Nanotechnology 24 335202
Google Scholar
[15] Fanelli F, Fracassi F 2016 Plasma Process Polym. 13 470
Google Scholar
[16] Pothiraja R, Bibinov N, Awakowicz P 2011 J. Phys. D Appl. Phys. 44 355206
Google Scholar
[17] Intranuovo F, Gristina R, Brun F, Mohammadi S, Ceccone G, Sardella E, Rossi F O, Tromba G, Favia P 2014 Plasma Process Polym. 11 184
Google Scholar
[18] Bashir M, Bashir S, Rees J M, Zimmerman W B 2014 Plasma Process Polym. 11 279
Google Scholar
[19] Fisher E R 2013 ACS Appl. Mater. Interfaces 5 9312
Google Scholar
[20] Hawker M J, Pegalajar-Jurado A, Fisher E R 2014 Langmuir 30 12328
Google Scholar
[21] Hensel K 2009 Eur. Phys. J. D 54 141
Google Scholar
[22] Babaeva N Y, Kushner M J 2014 Plasma Sources Sci. T. 23 065047
Google Scholar
[23] Hensel K, Katsura S, Mizuno A 2005 IEEE T. Plasma Sci. 33 574
Google Scholar
[24] Zhang Y, Wang H Y, Jiang W, Bogaerts A 2015 New J. Phys. 17 083056
Google Scholar
[25] Lu X, Wu S, Gou J, Pan Y 2014 Sci. Rep. 4 7488
Google Scholar
[26] Xu Y, Khrapak S A, Ding K, Schwabe M, Shi J J, Zhang J, Du C R 2019 arXiv: 1903.09379
[27] Jelil R A, Zeng X, Koehl L, Perwuelz A 2012 Text. Res. J. 82 1859
Google Scholar
[28] Píchal J, Klenko Y 2009 Eur. Phys. J. D 54 271
Google Scholar
[29] Feng C, Hu Y, Jin C, Zhuge L, Wu X, Wang W 2020 Plasma Sci. Technol. 22 015503
Google Scholar
[30] Huang B, Takashima K, Zhu X, Pu Y 2014 IEEE T. Plasma Sci. 42 2642
Google Scholar
[31] Šimor M, Ráhel’ J, Vojtek P, Černák M, Brablec A 2002 Appl. Phys. Lett. 81 2716
Google Scholar
[32] Čech J, Brablec A, Černák M, Puač N, Selaković N, Petrović Z L 2017 Eur. Phys. J. D 71 27
Google Scholar
[33] 张杰 2016 博士学位论文 (上海: 东华大学)]
Zhang J 2016 Ph. D. Dissertation (Shanghai: Donghua University) (in Chinese)[
[34] 张杰, 申亚军, 郭颖, 张菁, 石建军 2017 东华大学学报(自然科学版) 43 293
Google Scholar
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Google Scholar
[35] Zhang J, Guo Y, Shi Y C, Zhang J, Shi J J 2015 Phys. Plasmas 22 083502
Google Scholar
[36] Zhang J, Guo Y, Huang X J, Zhang J, Shi J J 2016 Plasma Sci. Technol. 18 974
Google Scholar
[37] Shi J J, Zhang J, Qiu G, Walsh J L, Kong M G 2008 Appl. Phys. Lett. 93 041502
Google Scholar
[38] Liu D W, Shi J J, Kong M G 2007 Appl. Phys. Lett. 90 041502
Google Scholar
[39] Balcon N, Hagelaar G J M, Boeuf J P 2008 IEEE T. Plasma Sci. 36 2782
Google Scholar
[40] Kraus M, Eliasson B, Kogelschatz U, Wokaun A 2001 Phys. Chem. Chem. Phys. 3 294
Google Scholar
[41] Zhang Y R, Van Laer K, Neyts E C, Bogaerts A 2016 Appl. Catal. B- Environ. 185 56
Google Scholar
[42] Feng F, Zheng Y, Shen X, Zheng Q, Dai S, Zhang X, Huang Y, Liu Z, Yan K 2015 Environ. Sci. Technol. 49 6831
Google Scholar
[43] Zhang Y, Wang H Y, Zhang Y R, Bogaerts A 2017 Plasma Sources Sci. T. 26 054002
Google Scholar
[44] Fanelli F, d'Agostino R, Fracassi F 2011 Plasma Process Polym. 8 932
Google Scholar
[45] Hensel K, Martišovitš V, Machala Z, Janda M, Leštinský M, Tardiveau P, Mizuno A 2007 Plasma Process Polym. 4 682
Google Scholar
[46] Kim H H 2000 Ph. D. Dissertation (Toyohashi: Toyohashi University of Technology)
[47] 李杰, 关银霞, 姜楠, 姚晓妹, 王世强, 刘全桢 2017 高压电技术 43 1759
Google Scholar
Li J, Guan Y X, Jiang N, Yao X M, Wang S Q, Liu Q Z 2017 High-Voltage Technol. 43 1759
Google Scholar
[48] Armenise V, Milella A, Fracassi F, Bosso P, Fanelli F 2019 Surf. Coat. Technol. 379 125017
Google Scholar
[49] Fanelli F, Bosso P, Mastrangelo A M, Fracassi F 2016 Jpn. J. Appl. Phys. 55 07LA01
Google Scholar
[50] Qin S C, Wang M, Wang C L, Jin Y C, Yuan N N, Wu Z C, Zhang J 2018 Adv. Mater. Interfaces 5 1800579
Google Scholar
[51] Jin Y C, Wang C L, Yuan N N, Ding K, Xu Y, Qin S C, Wang M, Wu Z C, Du C R, Shi J J, Zhang J 2019 Coatings 9 190
Google Scholar
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