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W3093025144 startingPage "124279" @default.
W3093025144 abstract "• Hybrid immobilization enabled continuous H 2 production from particulate biomass. • The highest average H 2 production rate was 9.82 L/L-d. • OLR affected H 2 production, metabolic flux, and microbial community. • Metabolic shift to non-H 2 production was found at over 80 g carbohydrate/L-d. • Population was shift from Clostridium sp. to propionate producers at high OLR. This study examined the feasibility of dark fermentative biohydrogen production from food waste using hybrid immobilization in mesophilic condition. Among four different organic loading rates (OLRs), the highest average hydrogen production rate (HPR) of 9.82 ± 0.30 L/L-d was found at an OLR of 74.7 g hexose/L-d, which was higher than reported values from particulate feedstock in mesophilic condition. The average hydrogen yield (HY) at the condition was 1.25 ± 0.04 mol H 2 /mol hexose consumed . Whereas the average HPR and HY at an OLR 80 g hexose/L-d were 5.82 ± 0.12 L/L-d and 0.64 ± 0.02 mol H 2 /mol hexose consumed , respectively. Metabolic flux analysis showed the low HY was concurrent with the highest propionic acid and homoacetogenis. Bacterial population was shift from Clostridium sp. to non-hydrogen producers including Bifidobacterium , Bacteriodes , Olsenella , Dysgonomonas , and Dialister sp." @default.
W3093025144 created "2020-10-22" @default.
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W3093025144 date "2021-01-01" @default.
W3093025144 modified "2023-09-24" @default.
W3093025144 title "High-rate mesophilic hydrogen production from food waste using hybrid immobilized microbiome" @default.
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W3093025144 doi "https://doi.org/10.1016/j.biortech.2020.124279" @default.
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