Sequential production of hydrogen and methane by anaerobic digestion of organic wastes: a review

Sequential production of hydrogen and methane by anaerobic digestion of organic wastes: a review

Energy and waste disposal issues are calling for advanced recycling methods such as conversion of organic waste into biohydrogen and biomethane. Here we review factors that influence yields, such as pH, temperature, substrate composition, biocatalyst, nutrient content, volatile fatty acids concentra...

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Bibliographic Details
Published in:Environmental chemistry letters Vol. 19; no. 2; pp. 1043 - 1063
Main Authors: Rawoof, Salma Aathika Abdur, Kumar, P. Senthil, Vo, Dai-Viet N., Subramanian, Sivanesan
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-04-2021
Springer Nature B.V
Subjects:
Additives
Anaerobic digestion
Anaerobic treatment
Analytical Chemistry
Biogas
Biohydrogen
Bioreactors
Carbon/nitrogen ratio
Chemical composition
Digestion
Earth and Environmental Science
Economics
Ecotoxicology
Environment
Environmental Chemistry
Fatty acids
Fermentation
Geochemistry
Hydraulic retention time
Hydrogen
Hydrogen production
Hydrogenase
Kinetics
Lignocellulose
Load distribution
Loading rate
Metabolomics
Methane
Methods
Microbial activity
Microorganisms
Mineral nutrients
Nutrient concentrations
Nutrient content
Nutrient retention
Nutrients
Optimization
Organic loading
Organic wastes
pH effects
Pollution
Pretreatment
Productivity
Reaction kinetics
Retention
Retention time
Review
Substrates
Trace metals
Volatile fatty acids
Waste disposal
Organic waste
Anaerobic fermentation
Biomethane
Biohydrogen
Pre-treatment
Co-digestion
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Description
Summary:Energy and waste disposal issues are calling for advanced recycling methods such as conversion of organic waste into biohydrogen and biomethane. Here we review factors that influence yields, such as pH, temperature, substrate composition, biocatalyst, nutrient content, volatile fatty acids concentration, organic loading rate, hydraulic retention time and C/N ratio. The optimum pH is 5.5–6 for hydrogen production, and 6.8–7.2 for methane production. Hydrogen yield improved highly after reducing the retention time from 72 to 20 h. The highest methane productivity was achieved with C/N ratio of 16–27. We also discuss methods to improve efficiency such as co-digestion, pre-treatment, application of additives and optimal digester design. Co-digestion synergizes the effects on microbial communities, balances the nutrients, reduces the inhibitory effects and improves the economic viability. Co-digestion has enhanced the productivity by 25–400% compared to mono-digestion. Acid pre-treatment is the best method for lignocellulose hydrolysis, followed by enzyme pre-treatment. Microwave pre-treatment enhances the biomethane production 4–7 times. The batch mode improves the substrate degradation efficiency and hydrogen production by 25% compared to the continuous mode. The addition of trace metals alters the hydrogenase activity during anaerobic fermentation. Reaction kinetics and metabolomics, bioaugmentation, digestate recirculation, frequent feeding and development of bioreactor systems for two-stage anaerobic digestion are also presented.
ISSN:1610-3653
1610-3661
DOI:10.1007/s10311-020-01122-6