Gravity-driven membrane system treating heavy metals-containing secondary effluent: Improved removal of heavy metals and mechanism

This study aimed at investigating the removal performance of the gravity-driven membrane (GDM) system in treating the heavy metals-containing secondary effluent, as well as evaluating the respective roles of Fe and Mn addition on the removal of heavy metals. GDM process with the formation of biocake...

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Published in:Chemosphere (Oxford) 2023-10, Vol.339, p.139590-139590, Article 139590
Main Authors: Ma, Xiaobin, Wang, Yanrui, Tong, Le, Luo, Jiaoying, Chen, Rui, Wang, Yuanxin, Guo, Xishou, Wang, Jinlong, Zhou, Zhiwei, Qi, Jingyao, Li, Guibai, Liang, Heng, Tang, Xiaobin
Format: Article
Language:English
Subjects:
Biocake layer
Gravity-driven membrane (GDM)
Heavy metal
Iron and manganese
Secondary effluent
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Summary:This study aimed at investigating the removal performance of the gravity-driven membrane (GDM) system in treating the heavy metals-containing secondary effluent, as well as evaluating the respective roles of Fe and Mn addition on the removal of heavy metals. GDM process with the formation of biocake layer exerted effective removals of Cr, Pb and Cd, with an average removal efficiency of 98%, 95% and 40%, respectively, however, after removing the biocake layer, the removal efficiencies of Cr, Pb and Cd reduced to 59%, 85% and 19%, respectively, indicating that the biocake layer played a fundamental role in removing heavy metals. With the assistance of Fe, the removal efficiency of heavy metals increased, and exhibited a positive response to the Fe dosage, due to the adsorption by the freshly generated iron oxides. On the contrary, the Mn involvement would result in the reduction of Cd removal due to the competitive adsorption of residual dissolved Mn2+ and Cd. Furthermore, the addition of a high dosage of Fe increased the diversity of eukaryotic communities and facilitated the elimination of heavy metals, however, the involvement of Mn would lead to a reduction in microbial diversity, resulting in a decrease of heavy metal removal efficiency. These findings are expected to develop new tactics to enhance heavy metal removal and promote widespread application of GDM technology in the fields of deep treatment of heavy metals-containing wastewater and reclamation of secondary effluent. [Display omitted] •More than 95% removal efficiency of Cr and Pb was obtained by GDM process.•Biocake layer played the fundamental role in the removal of heavy metals.•Higher removal efficiency of heavy metals was achieved with Fe addition.•Cd removal was decreased due to the competitive adsorption with residual Mn2+.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2023.139590