Photocatalytic mediated marine biofouling inhibition using nano CuO: TiO2-carbon dot embedded on organo silane surface modified polyethylene aquaculture cage nets

IF 4.1 2区 环境科学与生态学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
P Muhamed Ashraf, C.S. Anjana, N Manju Lekshmi
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引用次数: 0

Abstract

Biofouling in aquaculture cages is a potential problem and its management become major concern to the planners and farmers. The study aimed to modify the surface of polyethylene aquaculture cage nets using organo silane and to evaluate the effectiveness of a nano CuO:TiO2-carbon dot biocide treatment in inhibiting marine biofouling through photocatalytic action. Polyethylene aquaculture cage net surface modified using organo silane and the surface embedded with biocide of nano CuO:TiO2 and carbon dot (CD) derived from fish eye. The biocide-treated surface was characterized using UV–Visible and Fourier Transform Infrared spectrometry. The organo silane interacts with polyethylene via hydrogen bonding, CuO:TiO2 interacts with the silane's Si, and the carbon dots' conjugated CC bonds interact with the transition metal and silane through van der Waals electrostatic forces and hydrogen bonding. Varied concentrations of CuO:TiO2 and CD was coated sequentially over silane surface modified polyethylene, exposed in the marine environment to evaluate biofouling inhibition efficiency and found 0.05% each of CuO:TiO2 and CD was optimum. The CuO:TiO2–CD coated polyethylene cage net tested for its biofouling inhibition for 8 months in marine environment and exhibited excellent biofouling inhibition. The inhibition of biofouling was attributed to the enhanced photocatalytic action, resulting from increased electron-hole recombination, thus generating ROS, O2٠, and OH٠ radicals. This led to the highest electronic activity around the cage net and also the formation of an acidic environment deterred microorganisms. The study highlighted the use of organo silane for surface modification of polyalkenes to load the biocide and also CuO:TiO2–CD is a potential biocide for biofouling inhibition in aquaculture cages.

利用纳米 CuO:TiO2-碳点嵌入有机硅烷表面改性聚乙烯水产养殖网,进行光催化介导的海洋生物污损抑制作用
水产养殖网箱中的生物污损是一个潜在问题,其管理已成为规划者和养殖者关注的主要问题。本研究旨在使用有机硅烷改性聚乙烯水产养殖笼网表面,并评估纳米 CuO:TiO2 碳点杀菌剂处理通过光催化作用抑制海洋生物污损的效果。使用有机硅烷对聚乙烯水产养殖笼网表面进行改性,并在其表面嵌入从鱼眼中提取的纳米 CuO:TiO2 和碳点(CD)杀菌剂。使用紫外-可见光光谱法和傅立叶变换红外光谱法对经杀菌剂处理的表面进行了表征。有机硅烷通过氢键与聚乙烯相互作用,CuO:TiO 与硅烷的硅相互作用,碳点的共轭 CC 键通过范德华静电力和氢键与过渡金属和硅烷相互作用。将不同浓度的 CuO:TiO 和 CD 依次涂覆在硅烷表面改性的聚乙烯上,暴露在海洋环境中以评估生物污损抑制效率,结果发现 CuO:TiO 和 CD 的最佳浓度各为 0.05%。CuO:TiO-CD 涂层聚乙烯笼网在海洋环境中进行了长达 8 个月的生物污损抑制测试,结果表明其生物污损抑制效果极佳。抑制生物污损的原因是光催化作用增强,电子-空穴重组增加,从而产生了 ROS、O٠和 OH٠自由基。这使得笼网周围的电子活性最高,同时形成的酸性环境也对微生物产生了威慑作用。该研究强调了使用有机硅烷对聚烯烃进行表面改性以负载杀生物剂,同时 CuO:TiO-CD 也是一种潜在的杀生物剂,可用于抑制水产养殖网箱中的生物污垢。
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来源期刊
CiteScore
9.60
自引率
10.40%
发文量
107
审稿时长
21 days
期刊介绍: International Biodeterioration and Biodegradation publishes original research papers and reviews on the biological causes of deterioration or degradation.
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