Intermittent versus sequential dark-photo fermentative hydrogen production as an alternative for bioenergy recovery from protein-rich effluents

The anaerobic digestion of protein-based effluents generally has the risk of ammonia inhibition. While the use of dark-followed by photo-fermentation process, at acidic pH, could be useful for addressing this problem, the activity of photosynthetic bacteria is deteriorated at the low pH values. Henc...

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Bibliographic Details
Published in:Energy (Oxford) 2021-02, Vol.217, p.119326, Article 119326
Main Authors: Meky, Naira, Elreedy, Ahmed, Ibrahim, Mona G., Fujii, Manabu, Tawfik, Ahmed
Format: Article
Language:English
Subjects:
Ammonia
Ammonia inhibition
Anaerobic digestion
Bacteria
Biohydrogen
Compartments
Configuration management
Dark adaptation
Dark and photo fermentation
Effluents
Energy recovery
Fermentation
Gelatin
Hydrogen
Hydrogen energy
Hydrogen production
Microbial structure
pH effects
Photosynthesis
Protein-based feedstock
Proteins
Renewable energy
Rhodospirillaceae
rRNA 16S
Substrates
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Summary:The anaerobic digestion of protein-based effluents generally has the risk of ammonia inhibition. While the use of dark-followed by photo-fermentation process, at acidic pH, could be useful for addressing this problem, the activity of photosynthetic bacteria is deteriorated at the low pH values. Hence, in this study, intermittent dark-photo circular baffled reactor (IDP-CBR) was introduced to maintain the pH level (5.5–6.5), where biohydrogen is expected to be efficiently produced from gelatin-based substrate. We designed a four-compartments (i.e., C1 to C4) lab-scale IDP-CBR where C1 and C3 are dark-treated, and C2 and C4 are light-treated. The results revealed that peak hydrogen yield (HY) was achieved at initial gelatin of 2.0 gCOD/L, 24 h-HRT, and initial pH 6.5. The longer HRT provided better substrate conversion efficiency, and the use of higher pH (i.e., 6.5) promoted the photo-fermentation compartments (C2 and C4); further, this relatively acidic pH reduced the availability of free-ammonia. The 16S rRNA gene analysis showed that Clostridiaceae_1 and Rhodospirillaceae were the adapted bacteria that could produce dark- and light-dependent hydrogen, respectively. The comparison between IDP-CBR and the sequential configuration highlighted the superior performance of IDP-CBR in maintaining the medium pH, which promoted the light-dependent biohydrogen production (up to 13%). •Combined dark-photo fermentation of protein could avoid the ammonia-inhibition risk.•Intermittent four-chambers reactor (dark/photo/dark/photo) was examined at pH 
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2020.119326