氧化锌纳米颗粒与硫和氮的共轭对其能带隙、抗氧化特性和抗菌活性的影响

4区材料科学 Q2 Engineering

Advances in Materials Science and Engineering Pub Date : 2024-02-26 DOI:10.1155/2024/4275035

Diriba Yadesa, Jabessa Nagasa Guyasa, Tamene Tadesse Beyene

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引用次数: 0

摘要

氧化锌纳米粒子（ZnO-NPs）可用于工业、环境修复、催化和抗菌等多个领域。然而，由于其高能带隙和快速电子-空穴重组，其吸收可见光的能力受到限制，从而限制了其应用。为了提高 ZnO-NPs 在医疗和其他应用中的效率，可以通过掺杂来改变其表面功能。在此，我们研究了 S 和 N 掺杂对 ZnO-NP 能带隙及其抗菌和抗氧化活性的影响。结果表明，纯 ZnO-NPs 的光带隙能为 2.98 eV，而 6% N-ZnO、4% S-ZnO 和 S4-N6-ZnO 的光带隙能分别为 2.78、2.69 和 2.63 eV。能带隙的减小是由于掺杂后氧化锌的电子水平发生了变化。根据 XRD 数据并使用 FWHM 计算，纯 ZnO-NPs、6% N-ZnO、4% S-ZnO 和 S4-N6-ZnO 的晶体尺寸分别为 29.06、27.05、29.02 和 25.06 nm。随着带隙和粒径的减小，双掺杂 ZnO-NPs 的抗菌活性超过了纯 ZnO-NPs。此外，在优化浓度下，双掺杂 ZnO-NPs 的抗氧化活性从 52.45% 提高到 88.89%。因此，加入 S 和 N 作为双掺杂剂可以提高 ZnO-NPs 在各个领域的功能和效率。

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Effect of Codoping Zinc Oxide Nanoparticles with Sulfur and Nitrogen on Its Energy Bandgap, Antioxidant Properties, and Antibacterial Activity

Zinc oxide nanoparticles (ZnO-NPs) are used in various fields such as industrial, environmental remediation, catalytic, and antibacterial applications. However, their ability to absorb visible light is limited due to their high-energy bandgap and fast electron-hole recombination, which restricts their use. To enhance the efficiency of ZnO-NPs in medical and other applications, surface functionality can be modified through doping. Here, we investigated the effects of S and N doping on the energy bandgap of ZnO-NP and their antimicrobial and antioxidant activities. The results showed that the optical bandgap energy of pure ZnO-NPs was 2.98 eV while that of 6% N-ZnO, 4% S-ZnO, and S4-N6-ZnO was 2.78, 2.69, and 2.63 eV, respectively. The energy bandgap reduction is attributed to the changes in the electronic level of zinc oxide as the result of doping. The crystal size of pure ZnO-NPs, 6% N-ZnO, 4% S-ZnO, and S4-N6-ZnO was 29.06, 27.05, 29.02, and 25.06 nm, respectively, as calculated from XRD data using FWHM. Following the bandgap and particle size reduction, the antimicrobial activities of the dual-doped ZnO-NPs surpassed that of the pure ZnO-NPs. Moreover, dual doping improved the antioxidant activity of ZnO-NPs from 52.45% to 88.89% for the optimized concentration. Therefore, incorporating S and N as dual dopants can enhance the functionality and efficiency of ZnO-NPs in various fields.

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来源期刊

Advances in Materials Science and Engineering Materials Science-General Materials Science

CiteScore

3.30

自引率

0.00%

发文量

审稿时长

4-8 weeks

期刊介绍： Advances in Materials Science and Engineering is a broad scope journal that publishes articles in all areas of materials science and engineering including, but not limited to: -Chemistry and fundamental properties of matter -Material synthesis, fabrication, manufacture, and processing -Magnetic, electrical, thermal, and optical properties of materials -Strength, durability, and mechanical behaviour of materials -Consideration of materials in structural design, modelling, and engineering -Green and renewable materials, and consideration of materials’ life cycles -Materials in specialist applications (such as medicine, energy, aerospace, and nanotechnology)