Abstract
Improving the O3 activation via electrocatalysis is a promising approach to achieve higher hydroxyl radical ([rad]OH) production, however, the mechanisms and performance of electrocatalytic ozonation (ECO) remains unclear. Herein, we investigated the redox enhancement effect via preparing the asymmetric oxygen vacancies (OV) contained NiO-CeO2 and doped on carbon felt electrode to enhance anodic O3 activation for atrazine (ATZ) demineralization. XPS and ESR liquid analysis results revealed that OV content in NiO-CeO2 electrode are crucial sites for O3 decomposition and facilitating the [rad]OH generation. In situ Raman spectroscopy finding evidenced the intermetallic redox behaviour between NiO and CeO2 in ECO. As a result, ECO using NiO-CeO2 exhibited 3.4-times higher ATZ demineralization rate and 84.4% lower energy consumption (149 kWh/mg) than sole ozonation (960 kWh/mg). In addition, NiO-CeO2 electrode in ECO also showed excellent demineralization performance toward SMX and BPA. Meanwhile, the leaching of Ce(III) and Ni(II) from NiO-CeO2 were not detected in ECO. The toxicities of ATZ degradation by-products were reduced, as proved by QSAR predictions and seed germination. Notably, NiO-CeO2 electrode exhibited excellent reusability performance in consecutive seven cycles ECO tests and outstanding stability in continuous-stirred-tank-reactor experiments, with 84% ATZ demineralization for up to 10 hr. This study provides mechanistic insights into the roles of OV in redox enhancement to improve [rad]OH generation for water treatment.
Original language | English |
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Article number | 161174 |
Journal | Applied Surface Science |
Volume | 679 |
DOIs | |
State | Published - 15 Jan 2025 |
Bibliographical note
Publisher Copyright:© 2024 Elsevier B.V.
Keywords
- Electrocatalytic ozonation
- In situ Raman spectroscopy
- O activation
- Oxygen vacancies
- Redox reaction