揭示Moringa oleifera功能化混合多孔MOF-GO复合材料的染料吸附能力:通过抗菌和分子对接研究进行体外和硅学生态毒性评估

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Anil Kumar K., Arpit Bisoi, Yeshwanth M., Shobham, Mohan Jujaru, Jitendra Panwar and Suresh Gupta
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引用次数: 0

摘要

本研究证明了由铁& 铝金属有机框架(Fe-MOF 和 Al-MOF)及其氧化石墨烯复合材料(AlGC 和 FeGC)组成的可持续和生态友好型复合材料的合成。所开发复合材料的后合成表面功能化采用了油辣木叶粉提取物。使用标准技术对合成的 MOFs 和复合材料进行了表征。评估了合成的 MOFs 和复合材料去除废水中甲基橙(MO)和亚甲基蓝(MB)染料的能力。基于较高的染料去除能力,对功能化复合材料(AlGC 和 FeGC)进行了详细的染料吸附研究。采用田口优化设计对四个测试因子(即接触时间、初始染料浓度、复合材料用量和温度)进行优化,每个因子分为五个等级,以获得最高的染料吸附能力。复合材料对 MO(AlGC:577 ± 37,FeGC:631 ± 42 mg g-1)和 MB(AlGC:336 ± 13,FeGC:387 ± 7 mg g-1)染料的平衡吸附容量表现突出,是目前已报道的复合材料中最高的。应用等温线、动力学和热力学模型证实了两种染料的物理吸附都是自发的内热反应。再生研究表明,在三个吸附-解吸循环中,两种复合材料的染料去除率都超过了 65%,这证实了它们在工业规模上的可再利用性。通过对选定的具有重要生态意义的土壤细菌进行抗菌研究,以及对选定微生物的蛋白质靶标进行分子对接研究,分析了所开发复合材料的环境毒性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Unveiling the dye adsorption capability of Moringa oleifera functionalized hybrid porous MOF–GO composites: in vitro and in silico ecotoxicity assessment via antibacterial and molecular docking studies†

Unveiling the dye adsorption capability of Moringa oleifera functionalized hybrid porous MOF–GO composites: in vitro and in silico ecotoxicity assessment via antibacterial and molecular docking studies†

Unveiling the dye adsorption capability of Moringa oleifera functionalized hybrid porous MOF–GO composites: in vitro and in silico ecotoxicity assessment via antibacterial and molecular docking studies†

The present study demonstrated the synthesis of sustainable and eco-friendly composites composed of Fe & Al metal–organic frameworks (Fe-MOF and Al-MOF) and their graphene oxide composites (AlGC and FeGC). Post-synthetic surface functionalization of developed composites was done with Moringa oleifera leaves powder extract. The synthesized MOFs and composites were characterized using standard techniques. The ability of synthesized MOFs and composites to remove methyl orange (MO) and methylene blue (MB) dyes from wastewater was evaluated. Based on the higher dye removal ability, detailed dye adsorption studies were performed with functionalized composites (AlGC and FeGC). Taguchi optimization design was utilized to optimize the four testing factors, viz. contact time, initial dye concentration, composite dosage, and temperature, along with five levels for each factor to achieve the highest capacity for dye adsorption. The composites exhibited outstanding equilibrium adsorption capacities for MO (AlGC: 577 ± 37 and FeGC: 631 ± 42 mg g−1) and MB (AlGC: 336 ± 13 and FeGC: 387 ± 7 mg g−1) dyes, which are found to be the highest among the reported composites so far. Applying isotherms, kinetics, and thermodynamic models confirmed the spontaneous, endothermic reactions for the physisorption of both dyes. The regeneration studies showed more than ∼65% dye removal efficiency of both the composites up to three adsorption–desorption cycles, which confirms their reusability at the industrial scale. The environmental toxicity of developed composites was analyzed by antibacterial studies against selected ecologically important soil bacteria as well as by molecular docking studies against protein targets of selected microorganisms.

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CiteScore
7.20
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