Tang Xiaofeng, Xue Hanqing, Li Jiawen, Wang Shengnan, Yu Jie, Zeng Tao
Department of Environment Engineering, China Jiliang University, Hangzhou 310018, China.
Key Laboratory of Microbial Technology for Industrial Pollution Control of Zhejiang Province, Department of Environment, Zhejiang University of Technology, Hangzhou 310032, China.
Toxics. 2024 May 12;12(5):359. doi: 10.3390/toxics12050359.
Bisphenol A (BPA), representing a class of organic pollutants, finds extensive applications in the pharmaceutical industry. However, its widespread use poses a significant hazard to both ecosystem integrity and human health. Advanced oxidation processes (AOPs) based on peroxymonosulfate (PMS) via heterogeneous catalysts are frequently proposed for treating persistent pollutants. In this study, the degradation performance of BPA in an oxidation system of PMS activated by transition metal sites anchored nitrogen-doped carbonaceous substrate (M-N-C) materials was investigated. As heterogeneous catalysts targeting the activation of peroxymonosulfate (PMS), M-N-C materials emerge as promising contenders poised to overcome the limitations encountered with traditional carbon materials, which often exhibit insufficient activity in the PMS activation process. Nevertheless, the amalgamation of metal sites during the synthesis process presents a formidable challenge to the structural design of M-N-C. Herein, employing ZIF-8 as the precursor of carbonaceous support, metal ions can readily penetrate the cage structure of the substrate, and the N-rich linkers serve as effective ligands for anchoring metal cations, thereby overcoming the awkward limitation. The research results of this study indicate BPA in water matrix can be effectively removed in the M-N-C/PMS system, in which the obtained nitrogen-rich ZIF-8-derived Cu-N-C presented excellent activity and stability on the PMS activation, as well as the outstanding resistance towards the variation of environmental factors. Moreover, the biological toxicity of BPA and its degradation intermediates were investigated via the Toxicity Estimation Software Tool (T.E.S.T.) based on the ECOSAR system.
双酚A(BPA)作为一类有机污染物,在制药工业中有广泛应用。然而,其广泛使用对生态系统完整性和人类健康都构成了重大危害。基于过一硫酸盐(PMS)通过非均相催化剂的高级氧化工艺(AOPs)经常被用于处理持久性污染物。在本研究中,考察了双酚A在由锚定在氮掺杂碳质基底(M-N-C)材料上的过渡金属位点活化的过一硫酸盐(PMS)氧化体系中的降解性能。作为旨在活化过一硫酸盐(PMS)的非均相催化剂,M-N-C材料成为有望克服传统碳材料在PMS活化过程中活性不足这一局限性的有力竞争者。然而,合成过程中金属位点的合并对M-N-C的结构设计提出了巨大挑战。在此,以ZIF-8作为碳质载体的前驱体,金属离子能够轻易穿透基底的笼状结构,且富含氮的连接体作为锚定金属阳离子的有效配体,从而克服了这一尴尬的局限性。本研究的结果表明,水基质中的双酚A在M-N-C/PMS体系中能够被有效去除,其中所制备的富含氮的ZIF-8衍生的Cu-N-C在PMS活化方面表现出优异的活性和稳定性,以及对环境因素变化的出色抗性。此外,通过基于ECOSAR系统的毒性估计软件工具(T.E.S.T.)研究了双酚A及其降解中间体的生物毒性。
