SiC过渡层制备温度对碳化硅/氟化类金刚石复合薄膜血液相容性的影响

佘清; 江美福; 钱侬; 潘越

doi:10.7498/aps.63.185204

摘要

以316L不锈钢为基底，SiC晶体为靶材，Ar为源气体，采用磁控溅射法在不同温度下制备出系列SiC过渡层. 然后以高纯石墨作靶，Ar和CHF3为源气体，在同一工艺条件下再续镀一层氟化类金刚石（F-DLC）薄膜，形成SiC/F-DLC复合薄膜. 研究表明，相比于F-DLC薄膜，复合薄膜的附着力显著增加，血液相容性明显改善. 通过样品的拉曼和红外光谱分析了不同温度下制备的SiC过渡层以及复合薄膜结构的演变. 结果表明，控制SiC 过渡层制备温度可以有效调制过渡层中C=C键的比例以及-C-C-不饱和键的密度，复合薄膜中保留较高比例的芳香环式结构以及合适的F/C比是薄膜的血液相容性得以进一步改善的原因，SiC过渡层制备温度控制在500 ℃左右效果尤为明显. SiC 薄膜和F-DLC两种薄膜的界面处形成一定比例的Si-C键和C=C键是导致复合薄膜附着力显著上升的直接原因. 适当条件下在316L不锈钢和F-DLC薄膜之间增加SiC过渡层对于增强薄膜的附着力、改善其血液相容性是可行、有效的.

关键词:

Abstract

A series of SiC intermediate layers with different preparation temperatures is prepared by radio frequency magnetron sputtering on 316L stainless steel substrates by use of SiC crystal target and Argon as source gases. And then depositing fluorinated diamond-like carbon films (F-DLC) on a series of SiC intermediate layers under the same deposition condition with trifluromethane (CHF3) and Argon as source gases, and pure graphite as a target, a series of SiC/F-DLC composite films are obtained. The results show that the composite films have stronger adhesion and better hemocompatibility than that of the F-DLC films. The structure evolves with preparation temperatures of SiC intermediate layers and SiC/F-DLC composite films are studied by their Raman and Infrared transmission spectra. The results show that the proportion of C=C bonds and density of C-C unsaturated bonds in the SiC intermediate layers can be modulated by controlling the preparation temperature of SiC intermediate layers. The composite films have better hemocompatibility, especially with about 500 ℃ preparation temperature, may be attributed to holding higher proportion of aromatic ring structure and higher ratio of F/C in the composite films than the others. Formation of a considerable number of Si-C bonds and C=C bonds between SiC and F-DLC films may be the direct cause of strong adhesion. The addition of modest SiC intermediate layers between 316L stainless steel substrates and F-DLC films is feasible and effective to enhance films adhesion and improve film hemocompatibility.

Keywords:

作者及机构信息

1.
苏州大学物理科学与技术学院, 苏州 215006

基金项目: 国家自然基金（批准号：11275136）资助的课题.

Authors and contacts

1.
School of Physical Science and Technology, Suzhou University, Suzhou 215006, China

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 11275136).

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施引文献

[1]	Park J B, Kim Y K 2003 Biomaterials Principles and Applications (Boca Raton: CRC Press) p1
[2]	Brunski J B 2004 Biomaterials Science an Introduction to Materials in Medicine (San Diego: Elsevier Academic Press) p137
[3]	Haidopoulos M, Turgeon S, Sarra-Bournet C 2006 Mater. Sci.: Mater. Med. 17 647
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[5]	Gutensohn K, Beythien C, Bau J, Fenner T, Grewe P, Koester R, Padmanaban K, Kuehnl P 2000 Thrombosis Research 99 577
[6]	Ding M H, Wang B L, Li L, Zheng Y F 2010 Surf. Coat. Technol. 204 2519
[7]	Gorbet M B, Sefton M V 2004 Biomaterials 25 5681
[8]	Armitage D A, Parker T L, Grant D M 2003 Biomed. Mater. Res. A 66 129
[9]	Han Y Y, Guo H, Yin F Z, Zhang X M, Chu K, Fan Y M 2012 Rare Metals 31 58
[10]	Huang Y J, Wang Q, Wang M, Fei Z Y, Li M S 2011 Rare Metals 31 198
[11]	Wang J, Liu G C, Wang L D, Deng X L, Xu J 2008 Chin. Phys. B 17 3113
[12]	Wang P J, Jiang M F, Xin Y, Du J L, Dai Y F 2010 Acta Phys. Sin. 59 8902(in Chinese)[王培君, 江美福, 辛煜, 杜记龙, 戴永丰 2010 59 8902]
[13]	Dai Y F, Jiang M F, Yiang Y S, Zhou Y 2011 Acta Phys. Sin. 60 118101(in Chinese)[戴永丰, 江美福, 杨亦赏, 周杨 2011 60 118101]
[14]	Hakovirta M, He X M, Nastasi M 2000 Appl. Phys. 88 1456
[15]	Hasebe T, Ishimaru T, Kamijo A, Yoshimoto Y, Yoshimura T, Yohena S, Kodama H, Hotta A, Takahashi K, Suzuki T 2007 Diamond Relat. Mater 16 1343
[16]	Yang Y S, Jiang G, Zhou Y, Jiang M F 2012 J. Suzhou Univ. 28 51(in Chinese)[杨亦赏, 江舸, 周杨, 江美福 2012 苏州大学学报 28 51]
[17]	Cooper J A, Agarwal A K, Hara K 1999 IEEE Trans. Electron Dev. 46 442
[18]	Son J I, Shim J H, Cho N H 2010 Curr. Appl. Phys. 10 S365
[19]	Lin S H, Chen Z M, Li L B, Ba Y T, Liu S J, Yang M C 2012 Physica. B 407 670
[20]	Pan Y, Zhao Q, Jiang G, Zhou Y, Jiang M F, Yang Y S 2013 Acta Phys. Sin. 62 015209(in Chinese)[潘越, 赵强, 江舸, 周杨, 江美福, 杨亦赏 2013 62 015209]
[21]	Ollendorf H, Schneider D 1999 Surf. Coat. Tech 113 86
[22]	Gorbet M B, Sefton M V 2004 Biomaterials 25 5681
[23]	Armitage D A, Parker T L, Grant D M 2003 Biomed. Mater. Res. A 66 129
[24]	Robertson J 2002 Mater. Sci. Eng. R 37 129
[25]	Hobert H, Dunken H H, Meinschien J, Stafast H 1999 Vib. Spectrosc. 19 205
[26]	Kuntumalla M K, Ojha H, Srikanth V V S S 2013 Thin Solid Films 541 62
[27]	Jiang M F, Ning Z Y 2006 Surf. Coat. Technol. 200 3682
[28]	Jiang M F, Ning Z Y 2004 Acta Phys. Sin. 53 1588(in Chinese)[江美福, 宁兆元 2004 53 1588]

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