| Title |
Redox-neutral electrochemical decontamination of hypersaline wastewater with high technology readiness level |
| ID_Doc |
29359 |
| Authors |
Zhang, G; Li, YQ; Zhao, CX; Gu, JB; Zhou, G; Shi, YF; Zhou, Q; Xiao, F; Fu, WJ; Chen, QB; Ji, QH; Qu, JH; Liu, HJ |
| Title |
Redox-neutral electrochemical decontamination of hypersaline wastewater with high technology readiness level |
| Year |
2024 |
| Published |
Nature Nanotechnology, 19.0, 8 |
| Abstract |
Industrial hypersaline wastewaters contain diverse pollutants that harm the environment. Recovering clean water, alkali and acid from these wastewaters can promote circular economy and environmental protection. However, current electrochemical and advanced oxidation processes, which rely on hydroxyl radicals to degrade organic compounds, are inefficient and energy intensive. Here we report a flow-through redox-neutral electrochemical reactor (FRER) that effectively removes organic contaminants from hypersaline wastewaters via the chlorination-dehalogenation-hydroxylation route involving radical-radical cross-coupling. Bench-scale experiments demonstrate that the FRER achieves over 75% removal of total organic carbon across various compounds, and it maintains decontamination performance for over 360 h and continuously treats real hypersaline wastewaters for two months without corrosion. Integrating the FRER with electrodialysis reduces operating costs by 63.3% and CO2 emissions by 82.6% when compared with traditional multi-effect evaporation-crystallization techniques, placing our system at technology readiness levels of 7-8. The desalinated water, high-purity NaOH (>95%) and acid produced offset industrial production activities and thus support global sustainable development objectives. |
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