Competent CuS QDs@Fe MIL101 heterojunction for Sunlight-driven degradation of pharmaceutical contaminants from wastewater

Q1 Environmental Science
M. Ahmed Mubarak , Reem Mohamed , Sameh Ahmed Rizk , Atef Samir Darwish , Osama Abuzalat , Mohamed Eid M. Ali
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引用次数: 0

Abstract

In this study, we introduce an advanced photocatalyst developed by integrating copper sulfide quantum dots (CuS QDs) with an iron-based metal–organic framework (MOF), specifically Fe MIL101. The resulting CuS QDs@Fe MIL101 photocatalyst is engineered to efficiently degrade meloxicam (MLX) under simulated sunlight. The heterojunctions were generated by incorporating different concentrations of CuS QDs (5 %, 10 %, 15 %, 20 %, and 50 %) into the Fe MIL101 MOF matrix using the microwave-assisted hydrothermal method. The results of the XRD and the TEM studies confirmed the formation of the heterojunctions, which maintain the structural integrity of both CuS QDs and Fe MIL101. The BET measurements indicated a decrease in surface area upon CuS QDs incorporation, attributed to porés blockage and structural modifications. UV–Vis diffuse reflectance spectroscopy (DRS) revealed a redshift in absorption edges as CuS QDs content increased, enhancing visible light absorption. Photoluminescence (PL) investigations revealed that the 15 % CuS QDs@Fe MIL101 heterojunction had an effective charge separation and low recombination rates. The zeta potential analysis revealed a negative surface charge, indicating an overall electronegative characteristic. The photocatalytic performance, assessed through the degradation of MLX, demonstrated that the 15 % CuS QDs@Fe MIL101 heterojunction achieved the maximum degradation efficiency, reaching 96 % after 45 min of irradiation at a dosage of 0.1 g/L. This exceptional performance is attributed to potent charge separation, improving visible light absorption, high surface area and adsorption capacity. Various scavengers were used to investigate the roles of different reactive species, revealing holes as the predominant active species in the photocatalytic degradation process. These results highlight the potential of 15 % CuS QDs@Fe MIL101 heterojunctions as efficient photocatalyst for environmental remediation from pharmaceutical pollutants under simulated sunlight. These findings highlight the potential for application of CuS QDs@Fe MIL101 in real-world wastewater treatment systems, particularly in addressing pharmaceutical contaminants like meloxicam in industrial effluents.

Abstract Image

用于日光驱动的废水中药物污染物降解的 CuS QDs@Fe MIL101 异质结
在本研究中,我们介绍了一种先进的光催化剂,它是通过将硫化铜量子点(CuS QDs)与铁基金属有机框架(MOF)(特别是铁 MIL101)结合而开发的。由此产生的 CuS QDs@Fe MIL101 光催化剂可在模拟阳光下高效降解美洛昔康(MLX)。异质结是通过微波辅助水热法将不同浓度的 CuS QDs(5%、10%、15%、20% 和 50%)加入铁 MIL101 MOF 基体中生成的。XRD 和 TEM 研究结果证实了异质结的形成,异质结保持了 CuS QDs 和 Fe MIL101 结构的完整性。BET 测量结果表明,加入 CuS QDs 后,由于孔隙阻塞和结构改变,表面积有所减小。紫外-可见漫反射光谱(DRS)显示,随着 CuS QDs 含量的增加,吸收边缘发生了重移,从而增强了对可见光的吸收。光致发光(PL)研究表明,15% CuS QDs@Fe MIL101 异质结具有有效的电荷分离和较低的重组率。zeta电位分析表明其表面电荷为负,表明其具有整体电负性特征。通过降解 MLX 评估的光催化性能表明,15% CuS QDs@Fe MIL101 异质结实现了最高的降解效率,在 0.1 克/升的剂量下照射 45 分钟后,降解效率达到 96%。这种优异的性能归功于其强大的电荷分离能力、对可见光的吸收能力、高比表面积和吸附能力。研究人员使用了各种清除剂来研究不同反应物的作用,结果发现空穴是光催化降解过程中最主要的活性物。这些结果凸显了 15% CuS QDs@Fe MIL101 异质结作为高效光催化剂的潜力,可在模拟阳光下对制药污染物进行环境修复。这些发现凸显了 CuS QDs@Fe MIL101 在实际废水处理系统中的应用潜力,尤其是在处理工业废水中的美洛昔康等药物污染物方面。
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来源期刊
Environmental Nanotechnology, Monitoring and Management
Environmental Nanotechnology, Monitoring and Management Environmental Science-Water Science and Technology
CiteScore
13.00
自引率
0.00%
发文量
132
审稿时长
48 days
期刊介绍: Environmental Nanotechnology, Monitoring and Management is a journal devoted to the publication of peer reviewed original research on environmental nanotechnologies, monitoring studies and management for water, soil , waste and human health samples. Critical review articles, short communications and scientific policy briefs are also welcome. The journal will include all environmental matrices except air. Nanomaterials were suggested as efficient cost-effective and environmental friendly alternative to existing treatment materials, from the standpoints of both resource conservation and environmental remediation. The journal aims to receive papers in the field of nanotechnology covering; Developments of new nanosorbents for: •Groundwater, drinking water and wastewater treatment •Remediation of contaminated sites •Assessment of novel nanotechnologies including sustainability and life cycle implications Monitoring and Management papers should cover the fields of: •Novel analytical methods applied to environmental and health samples •Fate and transport of pollutants in the environment •Case studies covering environmental monitoring and public health •Water and soil prevention and legislation •Industrial and hazardous waste- legislation, characterisation, management practices, minimization, treatment and disposal •Environmental management and remediation
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