Factors influencing electrochemically enhanced sacrificial anode phosphate recovery

Xiaoyan Zhou; Gang Zhang; Haijian Shi

doi:10.1051/e3sconf/202123701005

All issues

Volume 237 (2021)

E3S Web Conf., 237 (2021) 01005

References

Open Access

Issue		E3S Web Conf. Volume 237, 2021 3^rd International Symposium on Architecture Research Frontiers and Ecological Environment (ARFEE 2020)


Article Number		01005
Number of page(s)		4
Section		Environmental Protection and Environmental Engineering
DOI		https://doi.org/10.1051/e3sconf/202123701005
Published online		09 February 2021

L. L. E Bayon. F. C. BallesterosJr., S. G Segura, M. C Lu, Water reuse nexus with resource recovery: On the fluidized-bed homogeneous crystallization of copper and phosphate from semiconductor wastewater. J. Clean. Prod, 236, 117705 (2019) [Google Scholar]
J. S Wei, X. G Meng, X. H Wen, Y. H Song, Adsorption and recovery of phosphate from water by amine fiber, effects of co-existing ions and column filtration. J Environ Sci-China, 87, 123 (2020). [Google Scholar]
Y. B Chu, M Li, J. W Liu, W Xu, S. H Cheng, Molecular insights into the mechanism and the efficiency-structure relationship of phosphorus removal by coagulation. Sci. Water Research, 147, 195 (2018). [Google Scholar]
D. J Kruk, M Elektorowicz, J. A Oleszkiewicz, Struvite precipitation and phosphorus removal using magnesium sacrificial anode. Sci. Chemosphere, 101, 28 (2014). [Google Scholar]
Y Gao, Y. W Xie, Q Zhang, Y. X Wang, L. Y Yang, Intensified nitrate and phosphorus removal in an electrolysis-integrated horizontal subsurface flow constructed wetland. Sci. Water Research, 108, 39 (2017). [Google Scholar]
X. X Ju, S. B Wu, Y. S Zhang, R. J Dong, Intensified nitrogen and phosphorus removal in a novel electrolysis-integrated tidal flow constructed wetland system. Sci. Water Research, 108, 37 (2017). [Google Scholar]
D. D Nguyen, H. H Ngo, W Guo, T. T Nguyen, S. W Chang, A Jang, Y. S Yoon, Can electrocoagulation process be an appropriate technology for phosphorus removal from municipal wastewater. Sci. Sci Total Environ, 563, 549 (2016). [Google Scholar]
V Kuokkanen, T Kuokkanen, J Ramo, U Lassi, J Roininen, Removal of phosphate from wastewaters for further utilization using electrocoagulation with hybrid electrodes-Techno-economic studies. Journal of Water Process Engineering, 8, 50 (2015). [Google Scholar]
A Shalaby, E Nassef, A Mubark, M Hussein, Phosphate removal from wastewater by electrocoagulation using aluminium electrodes. Sci. Environ Eng Sci, 1, 90 (2014). [Google Scholar]
X. Y Zheng, H. N Kong, D. Y Wu, C Wang, Y Li, H. R Ye, Phosphate removal from source separated urine by electrocoagulation using iron plate electrodes. Water Sci Technol, 60, 2929 (2009). [PubMed] [Google Scholar]
A Attour., G. N Ben, T. M Mouldi, F Lapicque, J. P Leclerc, Intensification of phosphate removal using electrocoagulation treatment by continuous pH adjustment and optimal electrode connection mode. Sci. Desalin Water Treat. 57, 13255 (2016). [Google Scholar]

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[1] L. L. E Bayon. F. C. BallesterosJr., S. G Segura, M. C Lu, Water reuse nexus with resource recovery: On the fluidized-bed homogeneous crystallization of copper and phosphate from semiconductor wastewater. J. Clean. Prod, 236, 117705 (2019) [Google Scholar]

[2] J. S Wei, X. G Meng, X. H Wen, Y. H Song, Adsorption and recovery of phosphate from water by amine fiber, effects of co-existing ions and column filtration. J Environ Sci-China, 87, 123 (2020). [Google Scholar]

[3] Y. B Chu, M Li, J. W Liu, W Xu, S. H Cheng, Molecular insights into the mechanism and the efficiency-structure relationship of phosphorus removal by coagulation. Sci. Water Research, 147, 195 (2018). [Google Scholar]

[4] D. J Kruk, M Elektorowicz, J. A Oleszkiewicz, Struvite precipitation and phosphorus removal using magnesium sacrificial anode. Sci. Chemosphere, 101, 28 (2014). [Google Scholar]

[5] Y Gao, Y. W Xie, Q Zhang, Y. X Wang, L. Y Yang, Intensified nitrate and phosphorus removal in an electrolysis-integrated horizontal subsurface flow constructed wetland. Sci. Water Research, 108, 39 (2017). [Google Scholar]

[6] X. X Ju, S. B Wu, Y. S Zhang, R. J Dong, Intensified nitrogen and phosphorus removal in a novel electrolysis-integrated tidal flow constructed wetland system. Sci. Water Research, 108, 37 (2017). [Google Scholar]

[7] D. D Nguyen, H. H Ngo, W Guo, T. T Nguyen, S. W Chang, A Jang, Y. S Yoon, Can electrocoagulation process be an appropriate technology for phosphorus removal from municipal wastewater. Sci. Sci Total Environ, 563, 549 (2016). [Google Scholar]

[8] V Kuokkanen, T Kuokkanen, J Ramo, U Lassi, J Roininen, Removal of phosphate from wastewaters for further utilization using electrocoagulation with hybrid electrodes-Techno-economic studies. Journal of Water Process Engineering, 8, 50 (2015). [Google Scholar]

[9] A Shalaby, E Nassef, A Mubark, M Hussein, Phosphate removal from wastewater by electrocoagulation using aluminium electrodes. Sci. Environ Eng Sci, 1, 90 (2014). [Google Scholar]

[10] X. Y Zheng, H. N Kong, D. Y Wu, C Wang, Y Li, H. R Ye, Phosphate removal from source separated urine by electrocoagulation using iron plate electrodes. Water Sci Technol, 60, 2929 (2009). [PubMed] [Google Scholar]

[11] A Attour., G. N Ben, T. M Mouldi, F Lapicque, J. P Leclerc, Intensification of phosphate removal using electrocoagulation treatment by continuous pH adjustment and optimal electrode connection mode. Sci. Desalin Water Treat. 57, 13255 (2016). [Google Scholar]