pH dependence of reactive oxygen species generation and pollutant degradation in Fe(II)/O2/tripolyphosphate system.

Chengwu Zhang, Anqi Yang, Bing Qin, Wei Zhao, Chuipeng Kong, Chuanyu Qin
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Abstract

It has been reported that tripolyphosphate (TPP) can effectively enhance the activation of O2 by Fe(II) to remove organic pollutants in the environment. However, the influence of solution pH on the generation and conversion of reactive oxygen species (ROS) and their degradation of pollutants in the Fe(II)/O2/TPP system needs further investigation. In this study, we demonstrated that O2•- and •OH were the main ROS responsible for degradation in the system at different pH conditions, and their formation rates were calculated using a steady-state model. Experiments combined with density functional theory (DFT) calculations showed that the p-nitrophenol (PNP) degradation pathway in the Fe(II)/O2/TPP system is regulated by solution pH. Specifically, at pH = 3, the existence of Fe(II) in the solution is dominated by [Fe(II)(HTPP)2]2-, which leads to a rapid conversion from O2 and HO2• to generate •OH, and PNP is primarily oxidatively degraded. However, at pH = 5/7, [Fe(II)(TPP)2]4- is taking the lead with which O2•- is accumulated in the solution due to the slow conversion to •OH in this condition, and the PNP is mainly reductively degraded. This study proposes a new strategy to achieve the targeted oxidative/reductive removal of different types of pollutants by simply varying the solution pH in the Fe(II)/O2/TPP system.

Fe(II)/O2/tripolyphosphate 系统中活性氧生成和污染物降解的 pH 值依赖性。
据报道,三聚磷酸钠(TPP)能有效增强铁(II)对氧气的活化作用,从而去除环境中的有机污染物。然而,在 Fe(II)/O2/TPP 系统中,溶液 pH 值对活性氧(ROS)的生成和转化及其对污染物降解的影响还需要进一步研究。在本研究中,我们证明了在不同的 pH 值条件下,O2-- 和 -OH 是该体系中导致降解的主要 ROS,并利用稳态模型计算了它们的形成率。实验结合密度泛函理论(DFT)计算表明,Fe(II)/O2/TPP体系中对硝基苯酚(PNP)的降解途径受溶液pH值的调节。具体来说,在 pH = 3 时,溶液中的 Fe(II) 以 [Fe(II)(HTPP)2]2- 为主,导致 O2 和 HO2- 快速转化生成 -OH,PNP 主要被氧化降解。然而,在 pH = 5/7 时,[Fe(II)(TPP)2]4- 起主导作用,由于在此条件下转化为 -OH 的速度较慢,溶液中积累了 O2-,PNP 主要被还原降解。本研究提出了一种新策略,只需改变 Fe(II)/O2/TPP 体系中溶液的 pH 值,就能有针对性地氧化/还原去除不同类型的污染物。
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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