Demonstration of simultaneous biological sulphate reduction and partial sulphide oxidation in a hybrid linear flow channel reactor

Demonstration of simultaneous biological sulphate reduction and partial sulphide oxidation in a hybrid linear flow channel reactor

[Display omitted] •Hybrid Linear Flow Channel supported simultaneous sulphate reduction and sulphide oxidation.•Efficient sulphate reduction in anaerobic bulk volume.•Good biomass retention by attachment to submerged carbon microfibers.•Floating biofilm created microenvironment for partial sulphide...

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Bibliographic Details
Published in:Journal of water process engineering Vol. 34; p. 101143
Main Authors: Marais, T.S., Huddy, R.J., Harrison, S.T.L., van Hille, R.P.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-04-2020
Subjects:
Floating sulphur biofilm
Semi-passive bioprocess
Sulphate reducing bacteria
Sulphide oxidising bacteria
Sulphide oxidising bacteria
Semi-passive bioprocess
Sulphate reducing bacteria
Floating sulphur biofilm
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Summary:[Display omitted] •Hybrid Linear Flow Channel supported simultaneous sulphate reduction and sulphide oxidation.•Efficient sulphate reduction in anaerobic bulk volume.•Good biomass retention by attachment to submerged carbon microfibers.•Floating biofilm created microenvironment for partial sulphide oxidation.•Bio-sulphur product recovered by harvesting biofilm. Semi-passive remediation systems have the potential to treat low-volume, sulphate-rich, mining impacted waters in a sustainable way. This paper describes the “proof of concept” evaluation of a hybrid linear flow channel reactor, capable of efficient biological sulphate reduction and partial oxidation of the sulphide to elemental sulphur. Key elements include a sulphate-reducing microbial community, immobilised onto carbon fibres and the rapid development of a floating sulphur biofilm at the air-liquid interface. The biofilm impedes oxygen mass transfer, creating a suitable pH-redox microenvironment for partial sulphide oxidation. Demonstration of the concept was successful, with near complete sulphate reduction (1 g/L feed), effective sulphide management (95–100 % removal) and partial recovery of sulphur by harvesting the biofilm. The biofilm re-formed within 24 h, with no decrease in volumetric sulphate reduction rate during this period. Colonisation of the carbon microfibers ensured biomass retention, suggesting the reactor could remain effective at high volumetric flow rates.
ISSN:2214-7144
2214-7144
DOI:10.1016/j.jwpe.2020.101143