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废水中有机污染物光催化降解的进展:利用酞菁及含酞菁材料的力量

Advances in photocatalytic degradation of organic pollutants in wastewaters: harnessing the power of phthalocyanines and phthalocyanine-containing materials.

作者信息

Gamelas Sara R D, Tomé João P C, Tomé Augusto C, Lourenço Leandro M O

机构信息

LAQV-REQUIMTE, Department of Chemistry, University of Aveiro 3810-193 Aveiro Portugal

Centro de Química Estrutural, Institute of Molecular Sciences, Departamento de Engenharia Química, Instituto Superior Técnico, Universidade de Lisboa 1049-001 Lisboa Portugal

出版信息

RSC Adv. 2023 Nov 20;13(48):33957-33993. doi: 10.1039/d3ra06598g. eCollection 2023 Nov 16.

DOI:10.1039/d3ra06598g
PMID:38019980
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10658578/
Abstract

Access to clean water is increasingly challenging worldwide due to human activities and climate change. Wastewater treatment and utilization offer a promising solution by reducing the reliance on pure underground water. However, it is crucial to develop efficient and sustainable methods for wastewater purification. Among the emerging wastewater treatment strategies, photocatalysis has gained significant attention for decomposing organic pollutants in water, especially when combined with sunlight and a recoverable photocatalyst. Heterogeneous photocatalysts have distinct advantages, as they can be recovered and reused without significant loss of activity over multiple cycles. Phthalocyanine dyes, with their exceptional photophysical properties, are particularly valuable for homogeneous and heterogeneous photocatalysis. By immobilizing these photosensitizers in various supports, hybrid materials extend their light absorption into the visible spectrum, complementing most supports' limited UV light absorption. The novelty and research importance of this review stems from its discussion of the multifaceted approach to treating contaminated wastewater with phthalocyanines and materials containing phthalocyanines. It highlights key aspects of each study, including photocatalytic efficiency, recyclability characteristics, investigation of the generation of oxygen species responsible for degradation, identification of the major degradation byproducts for each pollutant, and others. Moreover, the review includes tables that illustrate and compare the various phthalocyanines and supporting materials employed in each study for pollutant degradation. Additionally, almost all photocatalysts mentioned in this review could degrade at least 5% of the pollutant, and more than 50 photocatalysts showed photocatalytic rates above 50%. When immobilized in some support, the synergistic effect of the phthalocyanine was visible in the photocatalytic rate of the studied pollutant. However, when performing these types of works, it is necessary to understand the degradation products of each pollutant and their relative toxicities. Along with this, recyclability and stability studies are also necessary. Despite the good results presented in this review, some of the works lack those studies. Moreover, none of the works mentions any study in wastewater.

摘要

由于人类活动和气候变化,在全球范围内获取清洁水正变得越来越具有挑战性。废水处理和利用通过减少对纯净地下水的依赖提供了一个有前景的解决方案。然而,开发高效且可持续的废水净化方法至关重要。在新兴的废水处理策略中,光催化因能分解水中的有机污染物而备受关注,特别是与阳光和可回收光催化剂结合时。非均相光催化剂具有明显优势,因为它们可以被回收并重复使用,且在多个循环中活性不会有显著损失。酞菁染料具有优异的光物理性质,在均相和非均相光催化中特别有价值。通过将这些光敏剂固定在各种载体中,杂化材料将其光吸收扩展到可见光谱,补充了大多数载体有限的紫外光吸收。本综述的新颖性和研究重要性源于其对用酞菁和含酞菁材料处理受污染废水的多方面方法的讨论。它突出了每项研究的关键方面,包括光催化效率、可回收性特征、对负责降解的氧物种生成的研究、每种污染物主要降解副产物的鉴定等。此外,综述还包括表格,展示并比较了每项研究中用于污染物降解的各种酞菁和载体材料。此外,本综述中提到的几乎所有光催化剂都能降解至少5%的污染物,超过50种光催化剂的光催化速率高于50%。当固定在某些载体中时,酞菁的协同效应在研究污染物的光催化速率中可见。然而,在进行这类工作时,有必要了解每种污染物的降解产物及其相对毒性。与此同时,可回收性和稳定性研究也很有必要。尽管本综述呈现了良好的结果,但一些研究缺乏这些方面的研究。此外,没有一项研究提及在废水中的任何研究。

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