Photocatalysis and optical properties of ZnO nanostructures grown by MOCVD on Si, Au/Si and Ag/Si wafers

V. Karpyna, L. Myroniuk, D. Myroniuk, M. Bugaiova, L. Petrosian, O. Bykov, O. Olifan, V. Strelchuk, O. Kolomys, V. Romanyuk, K. Naumenko, L. Artiukh, O. Povnitsa, S. Zahorodnia, A. S. Ievtushenko
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引用次数: 0

Abstract

Zinc oxide nanostructures (NS) were grown on thin discontinuous films of noble metals of silver and gold in order to study their structure, optical properties as well as photocatalytic and antiviral activity. The paper presents the results of X-ray diffraction study, scanning electron microscopy study, photoluminescence and Raman measurements. X-ray diffraction experiments demonstrate similar patterns for all grown ZnO nanostructures. The SEM images of ZnO NS grown on Ag/Si and Au/Si wafers demonstrate more dense surface microstructure compared to ZnO NS grown on bare Si wafers. The most intensive ultraviolet and deep level emissions are observed for ZnO NS grown on Ag/Si wafers. Increase in thicknesses of Ag island film from 5 nm to 10 nm gives significant increase in intensity of ultraviolet and deep level emissions. Photocatalysis of grown ZnO nanostructures was studied by methyl orange dye degradation. Superior photocatalytic results are demonstrated by ZnO nanostructures grown on Ag/Si wafers, for which constants of dye degradation were twice higher than for ZnO nanostructures grown on Si and Au/Si substrates. The photocatalytic results correlates with photoluminescence spectra: more intensive photoluminescence in ultraviolet and visible ranges of optical spectrum leads to better photocatalytic performance. The cytotoxic effect of ZnO nanostructures was studied without photoactivation by the help of cell cultures MDCK and Hep-2 while the virucidal effect of ZnO nanostructures was studied by the help of Influenza A virus (H1N1) (strain FM / 1/47) and human adenovirus serotype 2 (HAdV2). ZnO nanostructures in a 1:10 dilution were not toxic to Hep-2 and MDCK cells. Most of the tested ZnO nanostructures exhibited no virucidal activity against human adenovirus serotype 2 (HAdV2) and influenza A virus (H1N1) (strain FM / 1/47) in the absence of photoexcitation.
MOCVD在Si、Au/Si和Ag/Si晶片上生长ZnO纳米结构的光催化和光学性质
为了研究氧化锌纳米结构的结构、光学性质以及光催化和抗病毒活性,我们在贵金属银和金的不连续薄膜上生长了氧化锌纳米结构。本文介绍了x射线衍射研究、扫描电镜研究、光致发光和拉曼测量的结果。x射线衍射实验表明,所有生长的ZnO纳米结构都具有相似的模式。在Ag/Si和Au/Si晶片上生长的ZnO NS的SEM图像显示,与在裸硅晶片上生长的ZnO NS相比,ZnO NS的表面微观结构更致密。在Ag/Si晶片上生长的ZnO NS具有最强的紫外辐射和深能级辐射。银岛膜厚度从5nm增加到10nm,紫外和深能级发射强度显著增加。研究了甲基橙染料降解生长ZnO纳米结构的光催化作用。在Ag/Si衬底上生长的ZnO纳米结构具有优异的光催化效果,其染料降解常数比在Si和Au/Si衬底上生长的ZnO纳米结构高两倍。光催化效果与光致发光光谱有关,在紫外光谱和可见光光谱范围内,光致发光越强,光催化性能越好。通过细胞培养MDCK和Hep-2研究了ZnO纳米结构在没有光激活的情况下的细胞毒作用,并通过甲型流感病毒(FM / 1/47)和2型人腺病毒(HAdV2)研究了ZnO纳米结构的杀病毒作用。1:10稀释的ZnO纳米结构对Hep-2和MDCK细胞没有毒性。在没有光激发的情况下,大多数ZnO纳米结构对人2型腺病毒(HAdV2)和甲型流感病毒(H1N1) (FM / 1/47株)没有杀病毒活性。
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