Optimization of Fenton-like reaction pathways using Ov-containing ZnO@nitrogen-rich porous carbon: the electron transfer and 1O2 triggered non-radical process

Abstract

With the development of persulfate-based Fenton-like catalysis, how to control the PDS reaction pathway is a great challenge. Herein, we prepared catalysts with nitrogen-rich porous carbon (NPC) layers and oxygen vacancy (Ov) sites for PDS activation to degrade sulfamethazine (SMZ). Results revealed that the ZnO@NPC/PDS system exhibited only non-radical pathways, which comprised the singlet oxygen (1O2) and electron transfer process. The intrinsic mechanism underlying the production of active species was further verified by comparing the results of the ZnO@NPC/PDS and ZnO@NPC-Etch/PDS systems, Raman analysis and DFT calculations. Adsorption of PDS by carbon layers resulted in the formation of a catalyst–PDS complex, which not only elongated the S–O bond and accelerated the decomposition of PDS to generate 1O2 but also provided access for electron transfer. Meanwhile, Ov sites increased electron density and electron migration strength, which promoted more electron transfer from Ovs to PDS molecules through nitrogen-rich porous carbon layers. Moreover, the ZnO@NPC/PDS system could maintain a degradation rate of >90% for SMZ in real water matrixes. T. E. S. T software prediction and toxicity tests were used to investigate environmental implications of degradation intermediates, which showed reduced ecological toxicity compared with SMZ. This work fabricated the ZnO@NPC/PDS system and explored the interaction between nitrogen-rich porous carbon layers and Ov to regulate the occurrence of non-radical pathways, which could provide a strategy to control the PDS reaction pathway.

Graphical abstract: Optimization of Fenton-like reaction pathways using Ov-containing ZnO@nitrogen-rich porous carbon: the electron transfer and 1O2 triggered non-radical process

Supplementary files

Article information

Article type
Paper
Submitted
17 avq 2024
Accepted
10 noy 2024
First published
22 noy 2024

Environ. Sci.: Nano, 2025, Advance Article

Optimization of Fenton-like reaction pathways using Ov-containing ZnO@nitrogen-rich porous carbon: the electron transfer and 1O2 triggered non-radical process

Z. Zhang, T. Xiong, H. Peng, H. Zhang, S. He, X. Liu, Y. Liu, W. Feng, Z. Yang and W. Xiong, Environ. Sci.: Nano, 2025, Advance Article , DOI: 10.1039/D4EN00749B

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