纯和mn掺杂氧化锌纳米粒子光催化降解甲基绿染料的研究

R. Akram, Adeena Fatima, Z. Almohaimeed, Z. Farooq, K. W. Qadir, Q. Zafar
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引用次数: 8

摘要

本文研究了纯氧化锌和锰掺杂氧化锌(2wt)。采用化学沉淀法合成了甲基绿(MG)纳米颗粒,并对其在自然光下光降解污染染料进行了表征。XRD结构分析表明,本征氧化锌和mn掺杂氧化锌均具有良好的结构。%)样品具有六方纤锌矿结构,具有适当的相纯度,清楚地表明没有任何外部杂质。锰在ZnO基体晶格中的掺入使ZnO的晶粒尺寸减小(21.10→18.76 nm),通过fesem表面形貌研究,观察到晶粒尺寸在50 ~ 100 nm之间的纳米颗粒型表面特征。上述两种观察结果在为光催化反应提供更大的活性区域和更高的表面积体积比方面具有优点。光物理性质研究表明,在mn掺杂ZnO纳米粒子中,由于带隙的扩大,吸收峰蓝移了5 nm(365→360 nm)。MG染料的降解动力学遵循准二级动力学,纯ZnO介导的降解效率为62.78%,mn掺杂ZnO (2 wt)介导的降解效率为66.44%。%)光催化剂在60分钟的阳光照射下。其中,纯ZnO的光催化反应速率(K) ~0.01792 min-1和r2 ~0.97992, mn掺杂ZnO的光催化反应速率(K) ~0.02072 min-1和r2 ~0.97299略高。综上所述,多种电荷转移途径的协同作用、e−/h+对电荷分离的改善、表面面积的改善以及羟基自由基的高效生成是mn掺杂ZnO光催化剂对MG染料具有高效光催化活性的原因。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Photocatalytic Degradation of Methyl Green Dye Mediated by Pure and Mn-Doped Zinc Oxide Nanoparticles under Solar Light Irradiation
Herein this study, pure and manganese- (Mn-) doped ZnO (2 wt. %) nanoparticles have been synthesized using the chemical precipitation method and characterized for the photodegradation of methyl green (MG) pollutant dye under natural sunlight. The structural analysis via XRD patterns has revealed that both intrinsic and Mn-doped ZnO (2 wt. %) samples have hexagonal wurtzite structures with appropriate phase purity, clearly indicating the absence of any external impurity. The incorporation of Mn in the host ZnO lattice has decreased the crystallite size (21.10 → 18.76 nm), and nanoparticle-type surface features with sizes in the 50–100 nm range have been observed through FESEM-based surface morphological studies. Both aforementioned observations have merit in providing more active area and a high surface area to volume ratio for photocatalytic reaction. The investigation of photophysical properties indicates that in Mn-doped ZnO nanoparticles, the absorption peak is blue-shifted by 5 nm (365 → 360 nm), due to the widening of the bandgap. The degradation kinetics of MG dye follow the pseudo-second-order kinetics, and the degradation efficiency has been observed to be 62.78% mediated by pure ZnO and 66.44% by Mn-doped ZnO (2 wt. %) photocatalyst under 60 minutes of sunlight irradiation. Specifically, the rate of photocatalytic reaction (K) ~0.01792 min-1 and R 2 ~0.97992 has been achieved for pure ZnO, whereas slightly higher (K) ~0.02072 min-1 and R 2 ~0.97299 have been observed for Mn-doped ZnO, respectively. Conclusively, the synergistic interactions with multiple charge transfer pathways, improvement of e−/h+ pair charge separation, improved surface area, and efficient generation of hydroxyl radicals are supposed to be responsible for the highly efficient photocatalytic activity of the Mn–doped ZnO photocatalyst for MG dye.
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