Advanced structured of MgO thin film for bio applications

被引:2
作者
Abdullah-Hamead A.A. [1 ]
机构
[1] Department of Materials Engineering, University of Technology
来源
Materials Science Forum | 2020年 / 1002卷
关键词
Anti Bactria; Magnesium selenate; Magnesium titanium oxide; Pulse Nd: YAG laser; Tri-metal oxide;
D O I
10.4028/www.scientific.net/MSF.1002.319
中图分类号
学科分类号
摘要
Extensive efforts to further promoting the Anti-Bacteria and structural properties of thin films to reach reliability and possibility of commercialization, the chemical Tri-metal oxide component was verification as Anti-Bacteria factor in this paper. Pure and mixed thin films of magnesium oxide MgO was prepared by evaporation assisted laser Nedmyum - YAG pulse Nd: YAG laser system, MgO enhanced by adding Ti and Se, at (0.5, 1, 1.5 and 2%) by weight percentage. After that, calcination is done at 400 °C for 30 min. Structural and anti-bacterial growth inspections were performed. Experimental results showed that structural properties have improved significantly with the development of a MgO thin films with tri-metal oxide; Magnesium titanium oxide Mg2TiO4 and Magnesium selenate MgSeO4 phases. Moreover, there has been an enhancement in anti-bacteria properties, which makes these thin films more reliable for protection against bacteria. © 2020 Trans Tech Publications Ltd, Switzerland.
引用
收藏
页码:319 / 330
页数:11
相关论文
共 45 条
[11]  
Rosa-Garcia S. C. D. L., Torres P. M, Cornelio S. G., Aguado M. A. C., Quintana P., Ortiz N. M. G., Antifungal Activity of ZnO and MgO Nanomaterials and Their Mixtures against Colletotrichum gloeosporioides Strains from Tropical Fruit, J NANOMATER, pp. 1-9, (2018)
[12]  
Tang Z. X., Lv B. F., MgO Nanoparticles as Antibacterial AGENT: Preparation and Activity, BRAZ J CHEM ENG, 31, pp. 591-601, (2014)
[13]  
Ge S., Wang G., Shen Y., Zhang Q., Jia D., Wang H., Dong Q., Yin T., Cytotoxic effects of MgO nanoparticles on human umbilical vein endothelial cells in vitro, IET NANOBIOTECHNOL, 5, pp. 36-40, (2011)
[14]  
Fang X. S., Ye C. H., Zhang L. D., Zhang J. X., Zhao J. W., Yan P., Direct Observation of the Growth Process of MgO Nanoflowers by a Simple Chemical Route, SMALL, 1, pp. 422-428, (2005)
[15]  
MajeedItab A. M. A., Rana F. H., Al-Jalil O. A., Fabrication of High Responsivity for MgO NPs/PSi Heterojunction Device by Sol-Gel Technique, SILICON-NETH, pp. 1-4, (2019)
[16]  
Campos G. S., German D. C., Valenzuela J. A. G., Leal M. C., Rios J. L. F., Gil M. M., Hu H., Lerma M. S., Controlled synthesis of Mg(OH)2 thin films by chemical solution deposition and their thermal transformation to MgO thin films, CERAM INT, 45, pp. 10356-10363, (2019)
[17]  
Wang F., Ta N., Shen W., MgO nanosheets, nanodisks, and nanofibers for the Meerwein– Ponndorf–Verley reaction, APPL CATAL A-GEN, 475, pp. 76-81, (2014)
[18]  
Diachenko O. V., Opanasuyk A. S., Kurbatov D. I., Opanasuyk N. M., Kononova O. K., Namb D., Cheong H., Surface Morphology, Structural and Optical Properties of MgO Films Obtained by Spray Pyrolysis Technique, ACTA PHYS POL A, 130, pp. 805-810, (2016)
[19]  
Liu H., Mao X., Cui J., Jiang S., Zhang W., Investigation of high temperature electrical insulation property of MgO ceramic films and the influence of annealing process, CERAM INT, 45, pp. 24343-24347, (2019)
[20]  
Sinha M., Gupta M., Jonnard P., Modi M., Soft X-ray characterization of ion beam sputtered magnesium oxide (MgO) thin film, SURF INTERFACE ANAL, 50, pp. 1145-1148, (2018)
12345