低温制备不锈钢表面含铜磷酸铝涂层及抗菌性能研究

doi:10.15541/jim20160384

无机材料学报 ›› 2017, Vol. 32 ›› Issue (4): 431-436.DOI: 10.15541/jim20160384 CSTR: 32189.14.10.15541/jim20160384

低温制备不锈钢表面含铜磷酸铝涂层及抗菌性能研究

王东微, 董英豪, 周杰, 段可, 鲁雄, 汪建新, 冯波, 屈树新, 翁杰

(西南交通大学材料科学与工程学院, 材料先进技术教育部重点实验室, 成都610031)

收稿日期:2016-06-17 修回日期:2016-10-09 出版日期:2017-04-20 网络出版日期:2017-03-24
作者简介:王东微(1985–), 女, 博士研究生. E-mail: wdw_swjtu@163.com
基金资助:
国家自然科学基金 (51372210, 51572228);教育部博士点基金(20130184110023);四川省应用基础研究计划(2016JY0011)

Low-temperature Preparation of Cu-containing Aluminum Phosphate Coatings on Stainless Steel and Antibacterial Properties

WANG Dong-Wei, DONG Ying-Hao, ZHOU Jie, DUAN Ke, LU Xiong, WANG Jian-Xin, FENG Bo, QU Shu-Xin, WENG Jie

(Key Laboratory of Advanced Technologies of Materials, Ministry of Education, School of Materials Science and Engineering, Southwest Jiaotong University, Chengdu 610031, China)

Received:2016-06-17 Revised:2016-10-09 Published:2017-04-20 Online:2017-03-24
About author:WANG Dong-Wei. E-mail: wdw_swjtu@163.com
Supported by:
National Natural Science Foundation of China (51372210, 51572228);Ph.D Program Foundation of MOE (20130184110023);Basic Applied Research Program of Sichuan Province (2016JY0011)

摘要/Abstract

摘要：

利用磷酸二氢铝的固化反应在316不锈钢表面制备了不同含量Cu²⁺的磷酸铝涂层(Cu: Al=0.025、0.05、0.1)。差示扫描量热分析及X射线衍射表明涂层材料可在≤250℃下固化, 主要固化产物为AlH₂P₃O₁₀∙2H₂O、AlPO₄和Al₈H₁₂(P₂O₇)₉。Cu²⁺加入后产生了含铜的新相Cu₂P₂O₇。与大肠杆菌共培养12 h后各含Cu²⁺涂层表现出抗菌性, 且抗菌能力与Cu²⁺含量正相关; 接触24 h后, 所有含Cu²⁺涂层表面均无活菌检出。菌悬液中加入EDTA有效抑制了涂层抗菌活性, 表明涂层抗菌性能来自表面溶出的Cu²⁺。拉伸试验表明涂层结合强度在14.5~18.1 MPa范围。与无涂层的不锈钢相比, 涂覆涂层后样品的腐蚀电流密度下降了2个数量级。

null

关键词: 铜, 磷酸铝, 涂层, 抗菌

Abstract:

Aluminum phosphate coatings containing different levels of Cu²⁺ ions (Cu/Al molar ratio: 0.025, 0.05, 0.1) were prepared on 316-stainless steel based on the curing reaction of monoaluminium phosphate (MAP). The curing behaviors of the starting materials and phase compositions of the cured products were studied by differential scanning calorimetry and X-ray diffraction, respectively. Results indicate that the copper-free MAP cures at ≤250℃ to form 3 major phases: AlH₂P₃O₁₀·2H₂O, AlPO₄, and Al₈H₁₂(P₂O₇)₉. When Cu²⁺ ions are introduced into the MAP, an additional phase of Cu₂P₂O₇appears in the cured product. E. coli was inoculated on the surfaces of coatings to evaluate their antibacterial properties. After co-culture with E. Coli for 12 h, all Cu²⁺-containing coatings exhibit antibacterial effect and show a positive association between Cu²⁺ content and antibacterial activity. After co-culture for 24 h, no viable bacteria remain on any Cu²⁺-containing coating. The addition of ethylenediaminetetraacetic acid to the culture medium substantially inhibits the antibacterial activities of all coatings, confirming that the antibacterial effect is attributed to the release of Cu²⁺ ions from coatings. Pull-out tests show that the bonding strengths of the coatings range between 14.5-18.1 MPa. Potentiodyanmic polarization indicates that the coatings reduce the corrosion current density of the stainless steel substrate by approximately two orders of magnitude.

Key words: copper, aluminum phosphate, coating, antibacterial

中图分类号:

TQ174

王东微, 董英豪, 周杰, 段可, 鲁雄, 汪建新, 冯波, 屈树新, 翁杰. 低温制备不锈钢表面含铜磷酸铝涂层及抗菌性能研究[J]. 无机材料学报, 2017, 32(4): 431-436.

WANG Dong-Wei, DONG Ying-Hao, ZHOU Jie, DUAN Ke, LU Xiong, WANG Jian-Xin, FENG Bo, QU Shu-Xin, WENG Jie. Low-temperature Preparation of Cu-containing Aluminum Phosphate Coatings on Stainless Steel and Antibacterial Properties[J]. Journal of Inorganic Materials, 2017, 32(4): 431-436.

图/表 7

图1 四种涂层材料的DSC曲线

Fig. 1 DSC curves of powders dried from coating solutions

图2 四种涂层材料固化产物的XRD图谱

Fig. 2 XRD patterns of powders dried from coating solutions after curing at 250℃

图3 (a) 316-SS(喷砂后), (b) 316-AlP, (c) 316-AlP-0.025Cu, (d) 316-AlP-0.05Cu和(e) 316-AlP-0.1Cu) 表面SEM照片; (f) EDS微区分析区域

Fig. 3 SEM micrographs of (a) 316 stainless steel (grit- blasted), (b) 316-AlP, (c) 316-AlP-0.025Cu, (d) 316-AlP- 0.05Cu, and (e) 316-AlP-0.1Cu; (f) regions of EDS micro- analysis

图4 (a) 316-AlP和(b) 316-AlP-0.05Cu涂层截面的SEM照片

Fig. 4 Cross-section SEM images of (a) 316-AlP and (b) 316-AlP-0.05Cu coatings (marked by arrows)

图5 (a)大肠杆菌在不同表面的存活率及(b)细菌在样品表面培养24 h后冲洗液培养后的菌落形成情况

Fig. 5 (a) Survival rates of E.coli on various surfaces and (b) bacterial colonies formed by culture of dilutes

图6 加入EDTA对涂层表面大肠杆菌生存率的影响

Fig. 6 Effect of EDTA addition to culture medium on survival rates of E.coli on various surfaces

图7 样品的动电位极化曲线

Fig. 7 Potentiodynamic polarization curves of samples

参考文献 22

[1]	KASSEM I I.Chinks in the armor: The role of the nonclinical environment in the transmission of Staphylococcus bacteria. American Journal of Infection Control, 2011, 39(7): 539-541.
[2]	CHERNOUSOVA S, MATTHIAS E.Silver as antibacterial agent: ion, nanoparticle, and metal. Angewandte Chemie International Edition, 2013, 52(6): 1636-1653.
[3]	HE H, WANG J, GO Q, et al.Ag-silica composite nanotubes with controlled wall structures for biomedical applications. Colloids and Surfaces B: Biointerfaces, 2013, 111: 693-698.
[4]	GRASS G, RENSING C, SOLIOZ M.Metallic copper as an antimicrobial surface. Applied and Environmental Micribiology, 2011, 77(5): 1541-1547.
[5]	WU Q, LI J, ZHANG W, et al.Antibacterial property, angiogenic and osteogenic activity of Cu-incorporated TiO2 coating. Journal of Materials Chemistry B, 2014, 39(2): 6738-6748.
[6]	NAN L, YANG W, LIU Y, et al.Antibacterial mechanism of copper-bearing antibacterial stainless steel against E. Coli. Journal of Materials Science and Technology, 2008, 24(2): 197-201.
[7]	ZHANG X Y, JIANG L, HUANG X B, et al.Improvement of antibacterial properties of stainless steel by combining plasma Cu and thermal diffusion. Journal of Inorganic Materials, 2012, 27(5): 519-523.
[8]	DAN Z, NI H, XU B, et al.Microstructure and antibacterial properties of AISI 420 stainless steel implanted by copper ions. Thin Solid Films, 2005, 492(1): 93-100.
[9]	TRAPALIS C C, KOKKORIS M, PERDIKAKIS G, et al.Study of antibacterial composite Cu/SiO2 thin coatings. Journal of Sol-Gel Science and Technology, 2003, 26(1/2/3): 1213-1218.
[10]	VASCONCELOS D C L, CARVALHO J A N, MANTEL M, et al. Corrosion resistance of stainless steel coated with Sol-Gel silica, Journal of Non-Crystalline Solids, 2000, 271(1): 135-139.
[11]	JAIN S, BUDIANSKY N D, HUDSON J L, et al.Surface spreading of intergranular corrosion on stainless steels. Corrosion Science, 2010, 52(3): 873-885.
[12]	HAN H, KIM D.Studies on curing chemistry of aluminum-chromium-phosphates as low temperature curable binders. Journal of Sol-Gel Science and Technology, 2003, 26(1/2/3): 223-228.
[13]	HE L, CHEN D, SHANG S.Fabrication and wear properties of Al2O3-SiC ceramic coatings using aluminum phosphate as binder. Journal of Materials Science, 2004, 39(15): 4887-4892.
[14]	HAWTHORNE H M, NEVILLE A, TROCZYNSKI T, et al.Characterization of chemically bonded composite-Sol-Gel based alumina coatings on steel substrates. Surface and Coatings Technology. 2004, 176(2): 243-252.
[15]	MUNOZ T, PRAKASH A M, KEVAN L, et al.Synthesis and characterization of CuAPO-5 molecular sieves: evidence for the framework incorporation of Cu (II) ions. Journal of Physical Chemistry, 1998, 102(8): 1379-1386.
[16]	LIUD M, YANG Q, TROCZYNSKI T.Sol-Gel hydroxyapatite coatings on stainless steel substrates. Biomaterials, 2002, 23(3): 691-698.
[17]	MORRIS J H, PERKINS P G, ROSE A E A, et al. The chemistry and binding properties of aluminium phosphates. Chemical Society Reviews, 1977, 6(2): 173-194.
[18]	GILMORE R. Phosphoric Acid, Purification, Uses, Technology, and Economics. Boca Raton: CRC Press, 2014: 280.
[19]	周长林. 微生物学与基础免疫学, 2版. 南京: 东南大学出版社, 2008: 123.
[20]	KURODA A, NOMURA K, OHTOMO R, et al.Role of inorganic polyphosphate in promoting ribosomal protein degradation by the Lon protease in E. coli. Science, 2001, 293(5530): 705-708.
[21]	MATHEWS S, HANS M, MUCKLICH F, et al.Contact killing of bacteria on copper is suppressed if bacteria-metal contact is prevented and is induced on iron by copper ions. Applied and Environmental Microbiology, 2013, 79(8): 2605-2611.
[22]	CHEN Z, ZHANG L, ZHOU K C.Research progress of phosphate inorganic binder for high temperature resistance. Materials Science and Engineering of Powder Metallurgy, 2009, 2(14): 74-82.

低温制备不锈钢表面含铜磷酸铝涂层及抗菌性能研究

Low-temperature Preparation of Cu-containing Aluminum Phosphate Coatings on Stainless Steel and Antibacterial Properties

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