Oxalate degradation by alkaliphilic biofilms acclimatised to nitrogen-supplemented and nitrogen-deficient conditions

T.N. Weerasinghe Mohottige; K.Y. Cheng; A.H. Kaksonen; R. Sarukkalige; M.P. Ginige

doi:10.1002/jctb.5424

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Oxalate degradation by alkaliphilic biofilms acclimatised to nitrogen-supplemented and nitrogen-deficient conditions

Journal article

Open access

Peer reviewed

Oxalate degradation by alkaliphilic biofilms acclimatised to nitrogen-supplemented and nitrogen-deficient conditions

T.N. Weerasinghe Mohottige, K.Y. Cheng, A.H. Kaksonen, R. Sarukkalige and M.P. Ginige

Journal of Chemical Technology & Biotechnology, Vol.93(3), pp.744-753

2017

DOI: https://doi.org/10.1002/jctb.5424

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Abstract

BACKGROUND Sodium oxalate is a key organic contaminant in many industrial wastewater such as alumina industry, which diminish the process yields and product quality. Given that Bayer process liquor is typically deficient in nitrogen (N), there is external supplementation of N in current full-scale biological treatment processes. This study, for the first time examines oxalate degradation under N deficient conditions in a comparative study using two parallel biofilm-reactors, one N-supplemented and the other under N-deficient conditions. Oxalate degradation rates and oxygen uptake rates (OUR) were determined at different bulk water dissolve oxygen (DO) set-points. RESULTS The results revealed that oxalate removal rates (33 – 111 mg/h.g biomass) linearly correlate with OUR (0 – 70 mg O2/h.g biomass) in the N-supplemented reactor. However, in the N-deficient reactor, a linear increase of oxalate removal was recorded only with DO upto ≤ 3 mg/L. Surprisingly, anaerobic oxalate removal was evident even in the presence of DO (up to 8 mg/L) in both reactors. Further elucidation revealed formate, acetate and methane by-products during anaerobic oxalate removal in both reactors. CONCLUSION This study revealed the feasibility of aerobic oxalate oxidation and fermentation under alkaline and N-deficient conditions. Further, this study confirms the critical role of DO in aerobic oxalate biodegradation.

Details

Title: Oxalate degradation by alkaliphilic biofilms acclimatised to nitrogen-supplemented and nitrogen-deficient conditions
Authors/Creators: T.N. Weerasinghe Mohottige (Author/Creator)
K.Y. Cheng (Author/Creator) - CSIRO Land and Water
A.H. Kaksonen (Author/Creator) - CSIRO Land and Water
R. Sarukkalige (Author/Creator)
M.P. Ginige (Author/Creator) - CSIRO Land and Water
Publication Details: Journal of Chemical Technology & Biotechnology, Vol.93(3), pp.744-753
Publisher: John Wiley and Sons Ltd
Identifiers: 991005540042707891
Copyright: © 2017 Society of Chemical Industry
Murdoch Affiliation: School of Engineering and Information Technology
Language: English
Resource Type: Journal article

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Collaboration types: Domestic collaboration
Citation topics: 7 Engineering & Materials Science; 7.229 Mineral & Metal Processing; 7.229.2385 Red Mud Valorization
Web Of Science research areas: Biotechnology & Applied Microbiology; Chemistry, Multidisciplinary; Engineering, Chemical; Engineering, Environmental
ESI research areas: Chemistry