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Improving the performance of bioelectrochemical sulfate removal by applying flow mode

Shixiang Dai, Falk Harnisch, Mohammad Sufian Bin‐Hudari, Nina Keller, Carsten Vogt, Benjamin Korth

2022Microbial Biotechnology10 citationsDOIOpen Access PDF

Abstract

Abstract Treatment of wastewater contaminated with high sulfate concentrations is an environmental imperative lacking a sustainable and environmental friendly technological solution. Microbial electrochemical technology (MET) represents a promising approach for sulfate reduction. In MET, a cathode is introduced as inexhaustible electron source for promoting sulfate reduction via direct or mediated electron transfer. So far, this is mainly studied in batch mode representing straightforward and easy‐to‐use systems, but their practical implementation seems unlikely, as treatment capacities are limited. Here, we investigated bioelectrochemical sulfate reduction in flow mode and achieved removal efficiencies ( E sulfate , 89.2 ± 0.4%) being comparable to batch experiments, while sulfate removal rates ( R sulfate , 3.1 ± 0.2 mmol L −1 ) and Coulombic efficiencies ( CE , 85.2 ± 17.7%) were significantly increased. Different temperatures and hydraulic retention times (HRT) were applied and the best performance was achieved at HRT 3.5 days and 30°C. Microbial community analysis based on amplicon sequencing demonstrated that sulfate reduction was mainly performed by prokaryotes belonging to the genera Desulfomicrobium , Desulfovibrio , and Desulfococcus , indicating that hydrogenotrophic and heterotrophic sulfate reduction occurred by utilizing cathodically produced H 2 or acetate produced by homoacetogens ( Acetobacterium ). The advantage of flow operation for bioelectrochemical sulfate reduction is likely based on higher absolute biomass, stable pH, and selection of sulfate reducers with a higher sulfide tolerance, and improved ratio between sulfate‐reducing prokaryotes and homoacetogens.

Topics & Concepts

SulfateFlow (mathematics)ChemistryMode (computer interface)Biochemical engineeringEnvironmental scienceComputer scienceProcess engineeringMechanicsEngineeringOrganic chemistryPhysicsOperating systemMicrobial Fuel Cells and BioremediationWastewater Treatment and Nitrogen RemovalMembrane-based Ion Separation Techniques
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