Abstract
Nitrate pollution in groundwater is a serious problem worldwide, as its concentration in many areas exceeds the WHO-defined drinking water standard (50 mg/L). Hydrogen-oxidizing bacteria (HOB) are a group of microorganisms capable of producing single-cell protein (SCP) using hydrogen and oxygen. Furthermore, HOB can utilize various nitrogen sources, including nitrate. This study developed a novel hybrid biological-inorganic (HBI) system that coupled a new submersible water electrolysis system driven by renewable electricity with HOB fermentation for in-situ nitrate recovery from polluted groundwater and simultaneously upcycling it together with CO2 into single-cell protein. The performance of the novel HBI system was first evaluated in terms of bacterial growth and nitrate removal efficiency. With 5 V voltage applied and the initial nitrate concentration of 100 mg/L, the nitrate removal efficiency of 85.52% and raw of 47.71% (with a broad amino acid spectrum) were obtained. Besides, the HBI system was affected by the applied voltages and initial nitrogen concentrations. The water electrolysis with 3 and 4 V cannot provide sufficient H2 for HOB and the removal of nitrate was 57.12% and 59.22% at 180 h, while it reached 65.14% and 65.42% at 5 and 6 V, respectively. The nitrate removal efficiency reached 58.40% and 50.72% within 180 h with 200 and 300 mg/L initial nitrate concentrations. respectively. Moreover, a larger anion exchange membrane area promoted nitrate removal. The monitored of the determination of different forms of nitrogen indicated that around 60% of the recovered nitrate was assimilated into cells, and 40% was bio-converted to N2. The results demonstrate a potentially sustainable method for remediating nitrate contaminant in groundwater, upcycling waste nitrogen, CO2 sequestration and valorization of renewable electricity into food or feed.
Original language | English |
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Article number | 122127 |
Journal | Water Research |
Volume | 263 |
Number of pages | 9 |
ISSN | 0043-1354 |
DOIs | |
Publication status | Published - 2024 |
Keywords
- Nitrate
- Hydrogen-oxidizing bacteria
- Single-cell protein
- Groundwater
- Carbon capture