Temperature-driven carboxylic acid production from waste activated sludge and food waste: Co-fermentation performance and microbial dynamics

[Display omitted] •Temperature had an impact on solubilisation and fermentation yields.•Volatile fatty acids profile was influenced by temperature.•Each temperature studied had its own microbial consortium.•Waste activated sludge microbiota had a key role on the microbial consortium.•Acetoclastic me...

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Bibliographic Details
Published in:Waste management (Elmsford) 2024-04, Vol.178, p.176-185
Main Authors: Perez-Esteban, N., Vives-Egea, J., Peces, M., Dosta, J., Astals, S.
Format: Article
Language:English
Subjects:
Mesophilic
Microbiome
Mixed culture fermentation
Organic fraction of municipal solid waste
Psychrophilic
Thermophilic
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Summary:[Display omitted] •Temperature had an impact on solubilisation and fermentation yields.•Volatile fatty acids profile was influenced by temperature.•Each temperature studied had its own microbial consortium.•Waste activated sludge microbiota had a key role on the microbial consortium.•Acetoclastic methanogens from WAS could thrive in the fermenters. This work aims to improve the continuous co-fermentation of waste activated sludge (WAS) and food waste (FW) by investigating the long-term impact of temperature on fermentation performance and the underpinning microbial community. Acidogenic co-fermentation of WAS and FW (70:30 % VS-basis) to produce volatile fatty acids (VFA) was studied in continuous fermenters at different temperatures (25, 35, 45, 55 °C) at an organic loading rate of 11 gVS/(L·d) and a hydraulic retention time of 3.5 days. Two batches of WAS (A and B) were collected from the same wastewater treatment plant at different periods to understand the impact of the WAS microbioota on the fermenters’ microbial communities. Solubilisation yield was higher at 45 °C (575 ± 68 mgCOD/gVS) followed by 55 °C (508 ± 45 mgCOD/gVS). Fermentation yield was higher at 55 °C (425 ± 28 mgCOD/gVS) followed by 35 °C (327 ± 17 mgCOD/gVS). Temperature also had a noticeable impact on the VFA profile. At 55 °C, acetic (40 %) and butyric (40 %) acid dominated, while acetic (37 %), butyric acid (31 %), and propionic acid (17 %) dominated at 35 °C. At 45 °C, an accumulation of caproic acid was detected which did not occur at other temperatures. Each temperature had a distinct microbial community, where the WAS microbiota played an important role. The biomass mass-balance showed the highest growth of microorganisms (51 %) at 35 °C and WAS_B, where a consumption of acetic acid was observed. Therefore, at 35 °C, there is a higher risk of acetic acid consumption probably due to the proliferation of methanogens imported from WAS.
ISSN:0956-053X
1879-2456
DOI:10.1016/j.wasman.2024.02.026