Advanced Textile Technology ›› 2023, Vol. 31 ›› Issue (6): 51-60.

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Degradation of organic pollutants by carbon black metal phthalocyanine in situ producing high valent iron

  

  1. 1.College of Fashion and Design, Jiaxing Vocational & Technical College, Jiaxing 314036, China; 2.Jiangsu New Vision Advanced Functional Fiber Innovation Center Co., Ltd., Suzhou 215228, China; 3.College of Materials Science and Engineering, Donghua University, Shanghai 201620, China
  • Online:2023-11-10 Published:2023-11-16

碳黑金属酞菁原位生高价铁氧降解有机污染物

  

  1. 1.嘉兴职业技术学院时尚设计学院,浙江嘉兴 314036;2.江苏新视界先进功能纤维创新中心有限公司,江苏苏州 215200;3.东华大学材料科学与工程学院,上海 201620
  • 作者简介:夏云(1983- ),男,江苏扬州人,讲师,博士,主要从事环境催化纤维的研究。
  • 基金资助:
    浙江省访问工程师项目(FG2022321);嘉兴市应用性基础研究项目(2023AY11019);嘉兴职业技术学院重点项目(jzyz202301);嘉兴职业技术学院高层次引才项目(22407030166);嘉兴职业技术学院培育项目(22407030179)

Abstract: The rapid development of industry, the intensification of urbanization and the growth of population make human's increath demand for clean freshwater resources year by year, but at the same time, human production and domestic wastewater was discharged into the environment, resulting in the scarce freshwater resources. Organic pollutants such as drugs, personal care products, are present at extremely low concentrations from ng/L to μg/L in water, but they can cause immeasurable damage to the environment and living organisms, it causes harm to the human body ultimately. So more and more researchers pay attention to the recycling of wastewater which comes from daily life, agricultural or industrial production.
In order to respond to the “dual carbon”strategic objectives, it is necessary to efficiently degrade and remove organic pollutants in water to achieve sustainable development. Biological enzymes have high catalytic activity and strong selectivity to substrates, we can use them to catalyze degradation of organic pollutants. However, the direct extraction of enzymes from organisms will bring high extraction cost, the change of the application environment of enzymes will significantly reduce their catalytic activity. So we designed an environmentally friendly bionic catalyst called peroxide mimicking enzyme which can catalyze the degradation of organic pollutants in water efficiently. In peroxide mimicking enzyme, iron hexadecachlorophthalocyanine (FePcCl16) worked as the active site, pyridine group (Py) acted as the fifth ligand, carbon black (CB) served as a protein skeleton. Inspired by the principle of peroxidase metabolizing drugs, we constructed the environmentally-friendly bionic catalytic system which used peroxide simulation enzyme as catalys, hydrogen peroxide as oxidant to catalyze the oxidative degradation of dexamethasone (DXMS). The results showed that the bionic catalytic system maintained high efficiency and stable degradation rate of DXMS in the range of temperature from 25℃ to 65℃,it showed that the simulated enzyme catalyst was not sensitive to temperature. The degradation rate of DXMS was 100% in 60 min in acid or neutral conditions. It can be seen that the catalytic system was better than that of Fenton system. At the same time, the catalytic system did not change the degradation rate of organic pollutants in the presence of inorganic salts, and the degradation rate of DXMS still reached 100%, indicated that the catalytic system still had a good catalytic oxidation degradation efficiency in complex water environment. However, the degradation rate of DXMS was reduced by 28% due to the rapid decomposition of H2O2 under alkaline conditions. Surprisingly, we found that the catalytic system had excellent recycling performance, the degradation rate of DXMS was still 95% after 6 cycles of use. By adding isopropyl alcohol (IPA) and p-benzoquinone (p-BQ) into the system as trapping agents of hydroxyl radical(·OH) and superoxide radical (O2▪-) respectively, electron spin resonance (EPR) detection of ⸱OH and O2▪- captured by 5,5-Dimethyl-1-pyrroline N-oxide (DMPO), gas chromatography-mass spectrometry (GC-MS) for the detection of dimethyl sulfone (DMSO) oxidation product confirmed that the main active species of DXMS in the catalytic system were high-valent iron oxo (Fe (IV)=O) active sites, followed by ⸱OH.
Degradation path analysis showed that the first path of DXMS degradation began with the dehydrogenation of C8 and C14, then hydroxylation, the second path of DXMS degradation started with the removal of HF at C8 and C9, then hydroxylation or demethylation at C19. After 60min, all the intermediate products generated small molecule organic acid (succinic acid) or mineralization. The construction of the bionic catalytic system provided a new perspective for sewage treatment.

Key words: carbon black, metal phthalocyanine, high-valent iron-oxo active species, degradation, organic pollutant

摘要: 为高效去除复杂水体环境中的有机污染物,制备过氧化物模拟酶催化剂,以双氧水为氧化剂,构建环境友好型的仿生催化体系,来催化降解水体中的地塞米松有机污染物。研究催化剂的形貌及结构特征,催化体系的催化性能、循环使用性能、催化机理、催化降解产物及最终产物。研究结果表明:所构筑的催化体系在温和(室温、中性)及复杂水体环境中(酸性、无机盐)对地塞米松的降解率均为100 %,但在碱性条件下,该催化体系对地塞米松的降解率因双氧化水分解过快而降低了28 %;该催化体系经过6次循环使用后,对地塞米松的降解率仍达到95 %;过氧化物模拟酶在双氧水的作用下产生对水体有机污染物降解起主要作用的高价铁氧活性种,而羟基自由基起次要作用;经过60 min反应,该催化体系将地塞米松降解为对环境不存在二次污染的小分子有机酸。该仿生催化体系的构筑为仿生催化材料在工业废水中的应用提供了新视角。

关键词: 碳黑, 金属酞菁, 高价铁氧活性种, 降解, 有机污染物