Potential of bio-hydrogen production from dark fermentation of crop residues: A review

This study provided an estimate of the potential of bio-hydrogen production from dark fermentation of crop residues on a worldwide scale. The different crop residues reviewed included sugarcane tops, leaves and bagasse, corn straw, corn cob and corn stover, wheat straw, rice straw and husk, soybean...

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Bibliographic Details
Published in:International journal of hydrogen energy 2019-06, Vol.44 (32), p.17346-17362
Main Author: Bundhoo, Zumar M.A.
Format: Article
Language:English
Subjects:
Bio-hydrogen
Dark fermentation
Energy potential
Field-based crop residues
Pre-treatment
Process-based crop residues
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Summary:This study provided an estimate of the potential of bio-hydrogen production from dark fermentation of crop residues on a worldwide scale. The different crop residues reviewed included sugarcane tops, leaves and bagasse, corn straw, corn cob and corn stover, wheat straw, rice straw and husk, soybean straw, oil palm trunk and empty fruit bunch, sugar beet pulp, cassava residue, barley straw and sweet sorghum bagasse. Among these crop residues, wheat and rice straws are produced in the highest amount although sugarcane dominates crop production on a worldwide scale. Based on the bio-hydrogen yields reported in literature, estimated worldwide bio-hydrogen potential is highest for untreated rice straw at 58,002 Mm3/year followed by untreated wheat straw at 34,680 Mm3/year. This corresponds to a bio-energy potential of 623 PJ/year and 373 PJ/year for raw rice straw and wheat straw respectively while pre-treatment of the crop residues significantly increases the bio-hydrogen and bio-energy potential. While dark fermentation of crop residues offers a huge bio-energy potential, the process suffers from several constraints that hinder its implementation. As such, coupling of the dark fermentation process with the anaerobic digestion process as a two-stage process seems the most economically viable option for large-scale implementation. •Crop residues represent a huge potential for global bio-hydrogen production.•Wheat and rice straws are generated in the highest amount each year.•Estimated global bio-energy potential is the highest for rice straw at 623 PJ/year.•Pre-treatments play a key role in improved bio-hydrogen production.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2018.11.098