Department of Chemical Engineering, Sri Sivasubramaniya Nadar College of Engineering, Kalavakkam, 603110, Tamil Nadu, India; Centre of Excellence in Water Research (CEWAR), Sri Sivasubramaniya Nadar College of Engineering, Kalavakkam, 603 110, Tamil Nadu, India.
Department of Chemical Engineering, Sri Sivasubramaniya Nadar College of Engineering, Kalavakkam, 603110, Tamil Nadu, India; Centre of Excellence in Water Research (CEWAR), Sri Sivasubramaniya Nadar College of Engineering, Kalavakkam, 603 110, Tamil Nadu, India.
Chemosphere. 2023 Apr;321:138069. doi: 10.1016/j.chemosphere.2023.138069. Epub 2023 Feb 8.
Worldwide environmental issues have been escalating with the growth of the global economy and become a vital problem. To solve the problems, we require an eco-friendly and sustainable binary catalyst for the degradation of Azo dye pollutants. In this work, magnetically reusable, multifunctional novel Mn-doped CdAlO nanoparticles were effectively fabricated by the co-precipitation approach. It was utilized for the degradation of two Azo dyes, exhibiting 96 and 98% Mn (0.050 M)-doped CdAlO removal rates under visible light illumination, and presenting improved photocatalytic capability than that of pure and other dopants. More notably, the Mn (0.050 M)-doped CdAlO catalyst was recycled using centrifuges without major loss and displays almost similar photodegradation behaviors for six successive runs. According to the ESR measurements, outcome and quenching tests affirmed that OH and h radicals were better reactive species responsible for Azo dyes removal. A possible photodegradation reaction mechanism underlying the elimination of Azo dyes by Mn (0.050 M)-doped CdAlO catalyst is also proposed. Elaborated analyzes by variable reaction parameters such as the role of reactive species and catalyst dosage, pH, COD and irradiation time in the degradation route was also discussed. We assume that our outcomes will provide novel insights into using a highly effectual Mn (0.050 M)-doped CdAlO catalyst, with possible applications in the treatment of both industrial and domestic wastewater.
全球环境问题随着全球经济的增长而不断升级,已成为一个至关重要的问题。为了解决这些问题,我们需要一种环保且可持续的二元催化剂,用于降解偶氮染料污染物。在这项工作中,通过共沉淀法有效地制备了可回收的磁性多功能新型 Mn 掺杂 CdAlO 纳米粒子。它被用于两种偶氮染料的降解,在可见光照射下,具有 96%和 98%的 Mn(0.050 M)掺杂 CdAlO 的去除率,并表现出比纯相和其他掺杂剂更高的光催化性能。更值得注意的是,Mn(0.050 M)掺杂 CdAlO 催化剂可以通过离心机回收,没有明显的损失,并且在六个连续运行中表现出几乎相似的光降解行为。根据 ESR 测量、结果和猝灭测试,证实 OH 和 h 自由基是去除偶氮染料的更好活性物质。还提出了 Mn(0.050 M)掺杂 CdAlO 催化剂去除偶氮染料的可能光降解反应机制。还讨论了通过改变反应参数(如活性物质和催化剂用量、pH 值、COD 和照射时间)在降解途径中的作用的详细分析。我们假设我们的研究结果将为使用高效 Mn(0.050 M)掺杂 CdAlO 催化剂提供新的见解,并可能应用于工业和家庭废水的处理。
