Investigation of Atmospheric Pressure Plasma Discharge and Its Application to Surface Modification of Blood-Filtering Material

被引:0
|
作者
唐晓亮
冯贤平
邱高
闫永辉
施芸城
机构
[1] Physics Department, Donghua University, Shanghai 200051, China ,Physics Department, Donghua University, Shanghai 200051, China
[2] Physics Department,University of Puerto Rico, San Juan,P.R. 00931-3343, USA ,Physics Department, Donghua University, Shanghai 200051, China ,Physics Department, Donghua University, Shanghai 200051, China ,Physics Department, Donghua University, Shanghai 20
来源
Plasma Science & Technology | 2004年 / 05期
关键词
dielectric barrier discharge; plasma diagnostics; PBT melt-blown nonwoven material;
D O I
暂无
中图分类号
O536 [辐射与测量];
学科分类号
摘要
Melt-blown polybutylene terephthalate (PBT) nonwoven materials treated by usingplasma is regarded as one of the excellent materials to filter white blood cells (WBC) from blood.In this paper, dielectric barrier discharge (DBD) plasma source at an improved quasi-stable at-mospheric pressure is achieved when discharge voltage, discharge current, and gap between theelectrodes are carefully controlled. This plasma source has been used to modify the surface ofPBT melt-blown nonwoven materials. Experimental results indicate that both the wettablity andpermeation of treated PBT melt-blown nonwoven materials are greatly improved.
引用
收藏
页码:2463 / 2466
页数:4
相关论文
共 50 条
  • [31] Surface modification of polyethylene (PE) films using dielectric barrier discharge plasma at atmospheric pressure
    Wang Kun
    Li Jian
    Ren Chunsheng
    Wang Dezhen
    Wang Younian
    PLASMA SCIENCE & TECHNOLOGY, 2008, 10 (04) : 433 - 437
  • [32] Surface Modification of Polyethylene (PE) Films Using Dielectric Barrier Discharge Plasma at Atmospheric Pressure
    王坤
    李建
    任春生
    王德真
    王友年
    Plasma Science and Technology, 2008, (04) : 433 - 437
  • [33] Surface modification of polyethylene and polypropylene in atmospheric pressure glow discharge
    Síra, M
    Trunec, D
    Stahel, P
    Bursíková, V
    Navrátil, Z
    Bursík, J
    JOURNAL OF PHYSICS D-APPLIED PHYSICS, 2005, 38 (04) : 621 - 627
  • [34] Surface modification of polystyrene by dielectric barrier discharge in atmospheric pressure
    Wang, Changquan
    Zhang, Guixin
    Fang, Zhi
    He, Xiangning
    Xu, Yong
    Zhenkong Kexue yu Jishu Xuebao/Journal of Vacuum Science and Technology, 2009, 29 (06): : 695 - 699
  • [35] The frequency effect on atmospheric pressure RF discharge surface modification
    Alexandrov, A. F.
    Kralkina, E. A.
    Pavlov, V. B.
    Savinov, V. P.
    Sergeenko, V. Yu.
    Timofeev, I. B.
    Bugrov, G. E.
    Vavilin, K. V.
    Plaksin, V. Yu.
    Mok, Young Son
    Lee, Heon-Ju
    JOURNAL OF CERAMIC PROCESSING RESEARCH, 2007, 8 (01): : 64 - 69
  • [36] Modification of Leather Surface with Atmospheric Pressure Plasma and Nanofinishing
    Kaygusuz, Meruyert
    Meyer, Michael
    Junghans, Frauke
    Aslan, Ahmet
    POLYMER-PLASTICS TECHNOLOGY AND ENGINEERING, 2018, 57 (04) : 260 - 268
  • [37] Atmospheric pressure plasma surface modification of carbon fibres
    Kusano, Y.
    Andersen, T. L.
    Michelsen, P. K.
    PROCEEDINGS OF THE 17TH INTERNATIONAL VACUUM CONGRESS/13TH INTERNATIONAL CONFERENCE ON SURFACE SCIENCE/INTERNATIONAL CONFERENCE ON NANOSCIENCE AND TECHNOLOGY, 2008, 100
  • [38] Atmospheric Pressure Plasma Hydrophilic Modification of a Silicone Surface
    Encinas, N.
    Dillingham, R. G.
    Oakley, B. R.
    Abenojar, J.
    Martinez, M. A.
    Pantoja, M.
    JOURNAL OF ADHESION, 2012, 88 (4-6): : 321 - 336
  • [39] PDMS surface modification using atmospheric pressure plasma
    Kim, Hui Taek
    Jeong, Ok Chan
    MICROELECTRONIC ENGINEERING, 2011, 88 (08) : 2281 - 2285
  • [40] Remote Plasma Device for Surface Modification at Atmospheric Pressure
    Reichen, Patrick
    Sonnenfeld, Axel
    von Rohr, Philipp Rudolf
    PLASMA PROCESSES AND POLYMERS, 2009, 6 : S382 - S386
12345