Towards Valeric Acid Production from Riboflavin-Assisted Waste Sludge: pH-Dependent Fermentation and Microbial Community

The fermentative valeric acid production is a carbon-neutral method for the disposal of waste sludge in municipal wastewater treatment plants. To overcome the bottlenecks of energy-consuming and slow hydrolysis and acidification during the fermentation process, riboflavin was supplemented to enhance...

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Published inWaste and biomass valorization Vol. 14; no. 3; pp. 833 - 845
Main Authors Shi, Binfang, Huang, Jingang, Lin, Yuanyuan, Han, Wei, Qiu, Shanshan, Zhang, Dong, Tang, Junhong, Hou, Pingzhi
Format Journal Article
LanguageEnglish
Published Dordrecht Springer Netherlands 01.03.2023
Springer Nature B.V
Subjects
Acid production
Acidification
Ammonia
Carbon
Engineering
Environment
Environmental Engineering/Biotechnology
Fatty acids
Fermentation
Genera
Industrial Pollution Prevention
Microorganisms
Municipal wastewater
Organic compounds
Organic matter
Original Paper
pH effects
Redox reactions
Renewable and Green Energy
Retention time
Riboflavin
Sludge
Sludge disposal
Solubilization
Taxonomy
Valeric acid
Vitamin B
Volatile fatty acids
Waste Management/Waste Technology
Wastewater treatment
Wastewater treatment plants
Valeric acid
Riboflavin
Alkaline
Fermentation
Microbial community
Waste sludge
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Summary:The fermentative valeric acid production is a carbon-neutral method for the disposal of waste sludge in municipal wastewater treatment plants. To overcome the bottlenecks of energy-consuming and slow hydrolysis and acidification during the fermentation process, riboflavin was supplemented to enhance the biological redox reaction. The effect of pH (3, 5, 7, 9, 11) on the production of total volatile fatty acids (VFAs) and valeric acid from waste sludge, and on the shift of microbial community was investigated. The results indicated that the release of organic compounds and nitrogen, the production of VFAs and valeric acid, and the associated microbial community were pH-dependent in riboflavin-assisted sludge fermentation systems. Higher pH (9, 11) and shorter retention time (12 days) benefited the valeric acid production, which achieved to 190.8 (mg COD / g VSS), accounting for 76.6% of the total VFAs. Meanwhile, the solubilization of organics and ammonia was up to 43.7% and 38.4%, respectively. Alkaline condition in riboflavin-assisted fermentation system reduced the taxonomy categories and enriched the bacteria phyla of Firmicutes and the associated genera species, which were responsible for the acidification process related to valeric acid production. The study provided scientific insights into the recovery of valuable organic matter from waste sludge to achieve carbon-neutral and sustainable society. Graphical Abstract
ISSN:1877-2641
1877-265X
DOI:10.1007/s12649-022-01900-z