Microbial iron reduction activating sodium percarbonate for improving the dewaterability of iron-rich sludge

[Display omitted] •A new microbial iron reduction activating AOP was applied for sludge conditioning.•The sludge dewaterability was greatly improved by MIR/SPC in full-scale treatment.•Iron source in sludge was re-utilized by microbial iron reduction for AOP activation.•Microbial iron reduction faci...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2023-09, Vol.471, p.144771, Article 144771
Main Authors: Sun, Lianpeng, Chen, Chuanhan, Zhou, Siru, Yuan, Weifang, Lu, Hui, Wang, Hao, Zhu, Xinzhe, Deng, Huanzhong, Li, Xiao-yan, Lin, Lin, Li, Ruo-hong
Format: Article
Language:English
Subjects:
Advanced oxidation process
Microbial iron reduction
Sludge conditioning
Sludge dewaterability
Sodium percarbonate
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Summary:[Display omitted] •A new microbial iron reduction activating AOP was applied for sludge conditioning.•The sludge dewaterability was greatly improved by MIR/SPC in full-scale treatment.•Iron source in sludge was re-utilized by microbial iron reduction for AOP activation.•Microbial iron reduction facilitated Fe(II)/Fe(III) redox cycle for enhanced AOP. Sludge conditioning is a critical process to improve sludge dewaterability. This research developed a novel iron-rich sludge conditioning method by microbial iron reduction activating sodium percarbonate (MIR/SPC) treatment. The sludge conditioning parameters were optimized. The results showed that the MIR/SPC treatment could significantly improve the sludge dewaterability. The optimal conditions for sludge conditioning are as follows: 5-day anaerobic MIR treatment, pH 3 and 1 g/L of SPC. Under the optimal condition, the CST value of the conditioned sludge was reduced by over two-thirds, and the moisture content of dewatered sludge was decreased to 51.5% in full-scale application. The critical mechanism of MIR-promoted advanced oxidation process (AOP) in sludge conditioning was explored. The facilitation of iron reduction by MIR under microbial-driven reductive condition promoted the generation of hydroxyl radicals. The improved AOP generate more ROSs to attack floc structure of sludge, modify the EPS properties and cell status, strengthen the hydrophobicity and flocculability of sludge, and propel the release of bound water for enhanced dewaterability.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2023.144771