Lee You-Yi, Cheng Hao-Chien, Fan Chihhao
Department of Bioenvironmental Systems Engineering, National Taiwan University Taiwan
RSC Adv. 2024 Apr 29;14(20):13926-13933. doi: 10.1039/d4ra00827h. eCollection 2024 Apr 25.
This study explored the influence of structural characteristics of organic contaminants on the degradation during an advanced oxidation process (AOP). The target contaminants were acetaminophen (ACT), bisphenol A (BPA), and tetracycline (TC). The Fenton process was selected as the model process in which major reactive species of hydroxyl radicals in most AOPs are generated for target compound degradation. The optimal reagent concentration ratio was [Fe]/[HO] = 0.5 mM/0.5 mM in an acidic condition, resulting in 83.49%, 79.01%, and 91.37% removals of ACT, BPA, and TC, respectively. Contrarily, the mineralization rates were apparently lower compared to their respective removal efficiencies. Experimental observation also suggested that the aromatic structure was rather difficult to degrade since their unsaturated electron clouds would hinder the attack of hydroxyl radicals due to electric repulsion. The preferred attacking sites of an aromatic ring differ due to the functional groups and structure symmetry. However, the electrophilic attack of the hydroxyl radical is the major reaction for decomposing aliphatic structures of cyclic or branched organics, resulting in the highest removal and mineralization of TC among these three tested chemicals. In addition, an apparent removal of a contaminant may not necessarily reduce its toxic impact on the environment.
本研究探讨了有机污染物的结构特征对高级氧化过程(AOP)中降解的影响。目标污染物为对乙酰氨基酚(ACT)、双酚A(BPA)和四环素(TC)。选择芬顿工艺作为模型工艺,在该工艺中,大多数AOPs中产生主要的活性物种羟基自由基以降解目标化合物。在酸性条件下,最佳试剂浓度比为[Fe]/[H₂O₂]=0.5 mM/0.5 mM,ACT、BPA和TC的去除率分别为83.49%、79.01%和91.37%。相反,矿化率明显低于各自的去除效率。实验观察还表明,芳香结构相当难降解,因为其不饱和电子云会因电排斥而阻碍羟基自由基的攻击。由于官能团和结构对称性的不同,芳香环的优先攻击位点也不同。然而,羟基自由基的亲电攻击是分解环状或支链有机物脂肪族结构的主要反应,导致这三种受试化学品中TC的去除率和矿化率最高。此外,污染物的明显去除不一定会降低其对环境的毒性影响。
