4.4 Article

Catalytic degradation of carbamazepine by surface-modified zerovalent copper via the activation of peroxymonosulphate: mechanism, degradation pathways and ecotoxicity

Journal

ENVIRONMENTAL TECHNOLOGY
Volume -, Issue -, Pages -

Publisher

TAYLOR & FRANCIS LTD
DOI: 10.1080/09593330.2023.2220889

Keywords

Ethylene glycol; degradation; carbamazepine; nano-zerovalent copper; PMS

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In this research, surface-modified nano zerovalent copper (nZVC) was successfully synthesized using a borohydride reduction method in solvents such as ethanol (ETOH), ethylene glycol (EG), and tween80 (T80). The as-synthesized material was thoroughly characterized for its morphological surface and crystal structural properties, and it was found that EG provided the best synthesis environment for nZVC. The catalytic efficiency of nZVC/EG was investigated, and it was enhanced by the inclusion of peroxymonosulphate (PMS) in the absence of light. The degradation products and pathways of CBZ were determined, and the ecotoxicity analysis of the degradation products was explored.
In this research work, surface-modified nano zerovalent copper (nZVC) was prepared using a simple borohydride reduction method. The spectroscopic and crystallographic results revealed the successful synthesis of surface-modified nano zerovalent copper (nZVC) using solvents such as ethanol (ETOH), ethylene glycol (EG) and tween80 (T80). The as-synthesized material was fully characterized for morphological surface and crystal structural properties. The results indicated that EG provides an excellent synthesis environment to nZVC compared to ETOH and T80 in terms of good dispersion, high surface area and excellent catalytic properties. The catalytic efficiency of nZVC/EG was investigated alone and with peroxymonosulphate (PMS) in the absence of light. The degradation results demonstrated that the involvement of PMS synergistically boosted the catalytic efficiency of synthesized nZVC/EG material. Furthermore, the degradation products (DPs) of CBZ were determined by GC-MS and subsequently, the degradation pathways were proposed. The ecotoxicity analysis of the DPs was also explored. The proposed (nZVC/EG/PMS) system is economical and efficient and thus could be applied for the degradation of CBZ from an aquatic system after altering the degradation pathways in such a way that results in harmless products.

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