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使用二氧化钛光催化降解布洛芬:对自由基的作用机制和优先攻击的见解。

Photocatalytic degradation of ibuprofen using titanium oxide: insights into the mechanism and preferential attack of radicals.

作者信息

Miranda Maicon Oliveira, Cabral Cavalcanti Wesley Eulálio, Barbosa Felipe Fernandes, Antonio de Sousa José, Ivan da Silva Francisco, Pergher Sibele B C, Braga Tiago Pinheiro

机构信息

Laboratório de Peneiras Moleculares (LABPMOL), Programa de Pós-graduação em Química, Universidade Federal do Rio Grande do Norte (UFRN) Av. Sen. Salgado FIlho, Campus Universitário, Lagoa Nova 59.078-970 Natal RN Brazil

Instituto Federal de Educação, Ciência e Tecnologia do Piauí (IFPI) Rodovia PI 213 Zona Rural 64235-000 Cocal PI Brazil.

出版信息

RSC Adv. 2021 Aug 16;11(44):27720-27733. doi: 10.1039/d1ra04340d. eCollection 2021 Aug 9.

DOI:10.1039/d1ra04340d
PMID:35480690
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9037810/
Abstract

The present work studied ibuprofen degradation using titanium dioxide as a photocatalyst. Mechanistic aspects were presented and the preferred attack sites by the OH˙ radical on the ibuprofen molecule were detailed, based on experimental and simple theoretical-computational results. Although some previous studies show mechanistic proposals, some aspects still need to be investigated, such as the participation of 4-isobutylacetophenone in the ibuprofen degradation and the preferred regions of attack by OH˙ radicals. The photodegradation was satisfactory using 0.03 g of TiO and pH = 5.0, reaching 100% decontamination in 5 min. The zeta potential curve showed the regions of attraction and repulsion between TiO and ibuprofen, depending on the pH range and charge of the species, influencing the amount of by-products formed. Different by-products have been identified by GC-MS, such as 4-isobutylacetophenone. Ibuprofen conversion to 4-isobutylacetophenone takes place through decarboxylation reaction followed by oxidation. The proposed mechanism indicates that the degradation of ibuprofen undergoes a series of elementary reactions in solution and on the surface. Three different radicals (OH˙, O ˙ and OOH˙) are produced in the reaction sequence and contribute strongly to the oxidation and mineralization of ibuprofen and by-products, but the hydroxyl radical has a greater oxidation capacity. The simple study using the DFT approach demonstrated that the OH˙ radical attacks preferentially in the region of the ibuprofen molecule with high electronic density, which is located close to the aromatic ring (C[double bond, length as m-dash]C bond). The presence of the OH˙ radical was confirmed through a model reaction using salicylic acid as a probe molecule.

摘要

本研究以二氧化钛为光催化剂,对布洛芬的降解进行了研究。基于实验和简单的理论计算结果,阐述了其作用机理,并详细说明了羟基自由基在布洛芬分子上的优先攻击位点。尽管之前的一些研究提出了作用机理,但仍有一些方面需要进一步研究,比如4-异丁基苯乙酮在布洛芬降解中的作用以及羟基自由基的优先攻击区域。使用0.03 g二氧化钛且pH = 5.0时,光降解效果令人满意,5分钟内去污率达到100%。zeta电位曲线显示了二氧化钛和布洛芬之间的吸引和排斥区域,这取决于pH范围和物种电荷,影响了副产物的生成量。通过气相色谱-质谱联用仪(GC-MS)鉴定出了不同的副产物,如4-异丁基苯乙酮。布洛芬通过脱羧反应继而氧化转化为4-异丁基苯乙酮。所提出的机理表明,布洛芬的降解在溶液中和表面经历了一系列基元反应。反应过程中产生了三种不同的自由基(羟基自由基、氧自由基和过氧羟基自由基),它们对布洛芬及其副产物的氧化和矿化有很大贡献,但羟基自由基具有更强的氧化能力。使用密度泛函理论(DFT)方法进行的简单研究表明,羟基自由基优先攻击布洛芬分子中电子密度高的区域,该区域靠近芳香环(碳-碳双键)。通过使用水杨酸作为探针分子的模型反应证实了羟基自由基的存在。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f624/9037810/34296006bbea/d1ra04340d-f8.jpg
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