Abstract
Microelectrodes can be used to obtain chemical profiles within biofilm microenvironments. For example, sulfate (SO42−) and hydrogen sulfide (H2S) microelectrodes can be used to study sulfate reduction activity in this context. However, there is no SO42− microelectrode available for studying sulfate reduction in biofilms. In this study, SO42− and H2S microelectrodes were fabricated and applied in the measurement of a wastewater membrane-aerated biofilm (MAB) to investigate the in situ sulfate reduction activity. Both the SO42− and H2S microelectrodes with a tip diameter of around 20 micrometers were successfully developed and displayed satisfying selectivity to SO42− and H2S, respectively. The Nernstian slopes of calibration curves of the fabricated SO42− electrodes were close to −28.1 mV/decade, and the R2 values were greater than 98%. Within the selected concentration range from 10−5 M (0.96 mg/L) to 10−2 M (960 mg/L), the response of the SO42− microelectrode was log-linearly related to its concentration. The successfully fabricated SO42− microelectrode was combined with the existing H2S microelectrode and applied on an environmental wastewater biofilm sample to investigate the sulfate reduction activity within it. The H2S and SO42− microelectrodes showed stable responses and good performance, and the decrease of SO42− with an accompanying increased of H2S within the biofilm indicated the in situ sulfate reduction activity. The application of combined SO42− and H2S microelectrodes in wastewater biofilms could amend the current understanding of sulfate reduction and sulfur oxidation within environmental biofilms based on only H2S microelectrodes.
Highlights
Biofilms play significant roles in wastewater treatment due to their environmental friendliness, cost effectiveness, and strong adaptability to wastewater quality as compared to other biological treatments
There have been studies focused on biofilm reactors that have proven useful for treating various wastewaters [3,4,5,6]
The membrane-aerated biofilm reactor (MABR) was inoculated with activated sludge to initiate the biofilm growth
Summary
Biofilms play significant roles in wastewater treatment due to their environmental friendliness, cost effectiveness, and strong adaptability to wastewater quality as compared to other biological treatments. Multispecies biofilms contain a high cell density and reflect complex metabolic activity [1,2]; their potential for in situ bioremediation of wastewater has been investigated. There have been studies focused on biofilm reactors that have proven useful for treating various wastewaters [3,4,5,6]. Previous studies have demonstrated the heterogeneous structure of wastewater biofilms [7]. There could be combined microbial processes within a single piece of biofilm with stratification, which could simultaneously include aerobic oxidation, nitrification, denitrification, and. Res. Public Health 2020, 17, 2023; doi:10.3390/ijerph17062023 www.mdpi.com/journal/ijerph
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