通过纳米技术、共掺杂和增强 rGO 来提高改性 Ho/Cr-FeNdO3-rGO 纳米复合材料去除酒石酸的催化活性

IF 44 1区医学 Q1 ENDOCRINOLOGY & METABOLISM

The Lancet Diabetes & Endocrinology Pub Date : 2024-10-10 DOI:10.1016/j.ceramint.2024.10.109

Basem Al Alwan, Muhammad Aadil, Awais Khalid, Amira Alazmi, Atef El Jery, Mazen R.Alrahili, Mousa M. Hossin, Muhammad Imran Saleem, Mostafa El-Khatib

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引用次数: 0

摘要

在此，我们采用湿法技术合成了一种掺杂 Ho/Cr 的新型磁性可回收 FeNdO3 包晶半导体。我们在半导体下面放置了一块 rGO 薄片作为支撑，从而制备出了一种纳米复合材料。我们使用 XRD、FTIR、TGA、SEM、PL、UV/Vis、I-V 和 BET 分析了合成的 FeNdO3（FNO-1）、Ho/Cr-FeNdO3（FNO-2）和 Ho/Cr-FeNdO3/rGO （FNO-3）样品的结构、热、形貌、光电、电气和表面特性。结构研究证实，FNO-1 和 FNO-2 样品为正方晶相，晶粒大小分别为 21.61 纳米和 18.2 纳米。对 FNO-3 的扫描电镜和热重分析表明，存在用 r-GO 修饰的包晶纳米颗粒 (NPs)。复合样品（FNO-3）有效地收集了光子，具有良好的电导率（0.43 mA/V）和光电流（42.6 mA），以及较大的比表面积（61 m2g-1），表明了共掺杂和 rGO 增强的积极影响。在可见光照射 70 分钟的条件下，FNO-1、FNO-2 和 FNO-3 光催化剂降解偶氮染料酒石酸的效率分别为 48.95%、65.2% 和 98.74%，表明纳米复合材料的光催化活性大大高于掺杂样品和原始样品。合成的纳米复合材料矿化鞑靼嗪的速率常数为 0.021 分钟-1，其中超氧自由基和自由电子是主要的反应物。本研究将纳米技术、掺杂技术和复合技术相结合，创造出了一种具有优异光催化性能的改性过氧化物材料，在水处理领域具有很大的应用潜力。

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Synergizing nanotechnology, codoping, and reinforcement with rGO to increase the catalytic activity of a modified Ho/Cr-FeNdO3-rGO nanocomposite for tartrazine removal

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Synergizing nanotechnology, codoping, and reinforcement with rGO to increase the catalytic activity of a modified Ho/Cr-FeNdO3-rGO nanocomposite for tartrazine removal

Herein, we used a wet technique to synthesize a novel magnetic retrievable FeNdO₃ perovskite semiconductor codoped with Ho/Cr. We created a nanocomposite by placing an rGO sheet under the semiconductor as a support. The structural, thermal, morphological, optoelectronic, electrical, and surface properties of the synthesized FeNdO₃ (FNO-1), Ho/Cr-FeNdO₃ (FNO-2), and Ho/Cr-FeNdO₃/rGO (FNO-3) samples were analysed using XRD, FTIR, TGA, SEM, PL, UV/Vis, I–V, and BET. A structural study confirmed that the FNO-1 and FNO-2 samples grew as orthorhombic phases with grain sizes of 21.61 and 18.2 nm, respectively. The SEM and TGA analyses of FNO-3 indicated the presence of perovskite nanoparticles (NPs) modified with r-GO. The composite sample (FNO-3) effectively harvested light photons and had a good conductance (0.43 mA/V) and photocurrent (42.6 mA) and a large specific surface area (61 m²g^-1), demonstrating the positive impact of codoping and rGO reinforcement. Under 70 min of visible light irradiation, the FNO-1, FNO-2, and FNO-3 photocatalysts degraded the azo dye tartrazine with efficiencies of 48.95%, 65.2%, and 98.74%, respectively, indicating the photocatalytic activity of the nanocomposite was considerably higher than those of the codoped and pristine samples. The synthesized nanocomposite mineralized tartrazine with a rate constant of 0.021 minute^-1, where superoxide radicals and free electrons were the predominant reactive species. In this study, nanotechnology, codoping, and compositing were integrated to create a modified perovskite material with exceptional photocatalytic performance and high application potential for water treatment.

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来源期刊

The Lancet Diabetes & Endocrinology ENDOCRINOLOGY & METABOLISM-

CiteScore

61.50

自引率

1.60%

发文量

371

期刊介绍： The Lancet Diabetes & Endocrinology, an independent journal with a global perspective and strong clinical focus, features original clinical research, expert reviews, news, and opinion pieces in each monthly issue. Covering topics like diabetes, obesity, nutrition, and more, the journal provides insights into clinical advances and practice-changing research worldwide. It welcomes original research advocating change or shedding light on clinical practice, as well as informative reviews on related topics, especially those with global health importance and relevance to low-income and middle-income countries. The journal publishes various content types, including Articles, Reviews, Comments, Correspondence, Health Policy, and Personal Views, along with Series and Commissions aiming to drive positive change in clinical practice and health policy in diabetes and endocrinology.