Photocatalytic degradation of azithromycin formulation in aqueous solution by doped titanium dioxide/fiberglass-rubberized silicone photocatalytic membrane

IF 4.6 3区环境科学与生态学 Q2 ENGINEERING, ENVIRONMENTAL

Sustainable Environment Research Pub Date : 2023-11-09 DOI:10.1186/s42834-023-00199-2

Giovanina-Iuliana Lupu, Cristina Orbeci, Constantin Bobirică, Liliana Bobirică, Elena Sorana Lazăr, Jeanina Pandele-Cusu, Marian Nicolae Verziu, Cristian Pîrvu, Roberta-Geanina Irodia

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Abstract

Abstract The objective of this work was to develop a novel photocatalytic membrane for the photocatalytic degradation of azithromycin formulation from aqueous solutions which, in addition to a high photocatalytic activity, should have a good mechanical and physico-chemical stability over time. Thus, the Nb-TiO 2 and Nb-Fe-TiO 2 photocatalysts were prepared by the solution combustion synthesis method, and then they were manually embedded in a fiberglass – rubberized silicone support. The mineralogical, morphological, and structural characterization of the obtained materials showed that both niobium and iron replace titanium in the titanium dioxide network, thus confirming the synthesis of new photocatalysts. The results of the photocatalytic oxidation tests showed a good photocatalytic activity of the developed photocatalytic membranes (degradation efficiency of up to 70% in the first 15 min of irradiation), this being on the one hand attributed to the increase of the specific surface of the photocatalyst by introducing niobium into the photocatalyst structure, and on the other hand due to the triggering of the Fenton photo oxidation mechanism due to the presence of trivalent iron in the photocatalyst structure. Also, the results indicated an excellent mechanical and physico-chemical resistance of the photocatalytic membranes, they are being practically inert to the harsh conditions in the photocatalytic reactor.

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掺杂二氧化钛/玻璃纤维橡胶硅橡胶光催化膜对水溶液中阿奇霉素配方的光催化降解

摘要:本研究的目的是开发一种新型光催化膜，用于从水溶液中光催化降解阿奇霉素制剂，该膜除了具有高光催化活性外，还应具有良好的机械和物理化学稳定性。为此，采用溶液燃烧合成的方法制备了nb - tio2和nb - fe - tio2光催化剂，然后将其人工嵌入玻璃纤维-橡胶硅胶支架中。所得材料的矿物学、形态和结构表征表明，铌和铁在二氧化钛网络中都取代了钛，从而证实了新型光催化剂的合成。光催化氧化试验结果表明，所研制的光催化膜具有良好的光催化活性(在照射前15分钟降解效率高达70%)，这一方面是由于在光催化剂结构中引入铌增加了光催化剂的比表面;另一方面由于光催化剂结构中三价铁的存在触发了Fenton光氧化机制。结果还表明，该光催化膜具有优异的机械和物理化学抗性，对光催化反应器中的恶劣条件几乎是惰性的。

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来源期刊

Sustainable Environment Research Multiple-

CiteScore

8.00

自引率

2.00%

发文量

审稿时长

30 weeks

期刊介绍： The primary goal of Sustainable Environment Research (SER) is to publish high quality research articles associated with sustainable environmental science and technology and to contribute to improving environmental practice. The scope of SER includes issues of environmental science, technology, management and related fields, especially in response to sustainable water, energy and other natural resources. Potential topics include, but are not limited to: 1. Water and Wastewater • Biological processes • Physical and chemical processes • Watershed management • Advanced and innovative treatment 2. Soil and Groundwater Pollution • Contaminant fate and transport processes • Contaminant site investigation technology • Soil and groundwater remediation technology • Risk assessment in contaminant sites 3. Air Pollution and Climate Change • Ambient air quality management • Greenhouse gases control • Gaseous and particulate pollution control • Indoor air quality management and control 4. Waste Management • Waste reduction and minimization • Recourse recovery and conservation • Solid waste treatment technology and disposal 5. Energy and Resources • Sustainable energy • Local, regional and global sustainability • Environmental management system • Life-cycle assessment • Environmental policy instruments