Enhanced simazine degradation via peroxymonosulfate activation using hemin-doped rice husk biochar as a novel Fe/N-C catalyst.

Chemosphere Pub Date : 2024-10-01 Epub Date: 2024-10-16 DOI:10.1016/j.chemosphere.2024.143549

Aaron Albert Aryee, Md Abdullah Al Masud, Won Sik Shin

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Abstract

The presence of herbicides, including simazine (SIM), in aquatic environments pose significant threats to these ecosystems, necessitating a method for their removal. In this study, a hemin-doped rice husk-derived biochar (RBC@Hemin_20%) was synthesized using a simple, one-step pyrolysis, and its degradation efficiency towards SIM via peroxymonosulfate (PMS) was assessed. Under optimized conditions (hemin loading = 20 wt%, SIM = 0.5 ppm, RBC@Hemin_20% catalyst = 0.2 g L^-1, PMS = 2.0 mM, and pH = 5.84 [unadjusted]), RBC@Hemin_20%, as an Fe/N-C catalyst, could activate PMS to achieve >99% degradation of SIM. Based on radical scavenger and electron spin resonance spectroscopy (ESR) experiments, both radical (^•OH and SO₄^•-) and non-radical (such as singlet oxygen, ¹O₂) mechanisms and electron transfer were involved in the degradation system. Significant mineralization (97.3%) and reusability efficiency (∼74.1% SIM degradation after 4 applications) were exhibited by the RBC@Hemin_20%/PMS system, which also maintained a remarkable degradation efficiency in tap-, river-, and ground-water. Additionally, the RBC@Hemin_20%/PMS system exhibited rapid degradation of tetracycline (TC) and diclofenac (DCF), indicating its prospects in the degradation of other organic pollutants of aquatic environments. The plausible degradation mechanism pathways of SIM are proposed based on identified intermediates. Finally, the toxicity of these intermediate products is analysed using the Ecological Structure Activity Relationship (ECOSAR) software. It is expected that this study will expand the current knowledge on the synthesis of efficient biomass-based Fe/N-C composites for the removal of organic pollutants in water.

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使用掺杂海明的稻壳生物炭作为新型铁/氮-碳催化剂，通过过一硫酸盐活化促进西玛津降解。

包括西玛津（SIM）在内的除草剂在水生环境中的存在对这些生态系统构成了严重威胁，因此有必要找到去除这些除草剂的方法。本研究采用简单的一步热解法合成了掺杂海明的稻壳衍生生物炭（RBC@Hemin20%），并评估了其通过过一硫酸盐（PMS）降解西玛津的效率。在优化条件下（hemin负载量 = 20 wt%，SIM = 0.5 ppm，RBC@Hemin20%催化剂 = 0.2 g L-1，PMS = 2.0 mM，pH = 5.84 [未调整]），RBC@Hemin20%作为一种Fe/N-C催化剂，可激活PMS，使SIM的降解率大于99%。根据自由基清除剂和电子自旋共振光谱（ESR）实验，自由基（-OH 和 SO4--）和非自由基（如单线态氧，1O2）机制和电子转移都参与了降解系统。RBC@Hemin20%/PMS 系统表现出显著的矿化度（97.3%）和可再利用效率（4 次使用后 SIM 降解率为 74.1%），在自来水、河水和地下水中也保持了出色的降解效率。此外，RBC@Hemin20%/PMS 系统还能快速降解四环素（TC）和双氯芬酸（DCF），这表明它在降解水生环境中的其他有机污染物方面具有广阔的前景。根据已确定的中间产物，提出了 SIM 的合理降解机制途径。最后，利用生态结构活动关系（ECOSAR）软件分析了这些中间产物的毒性。预计这项研究将扩展目前关于合成高效生物质基 Fe/N-C 复合材料以去除水中有机污染物的知识。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Chemosphere

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