A review on hydrothermal liquefaction of algal biomass on process parameters, purification and applications

•Conversion of algae biomass into bio-oil, biochar and biogas using hydrothermal liquefaction.•Algae is considered as a potential source due to its rapid growth and high flexibility.•The pathway of HTL involves de-polymerization, de-composition and recombination.•Carbohydrates, lipids and proteins w...

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Bibliographic Details
Published in:Fuel (Guildford) 2022-04, Vol.313, p.122679, Article 122679
Main Authors: Ravichandran, Sathish Raam, Venkatachalam, Chitra Devi, Sengottian, Mothil, Sekar, Sarath, Kandasamy, Sabariswaran, Ramasamy Subramanian, Kesav Prasath, Purushothaman, Kirubakaran, Lavanya Chandrasekaran, Aravindan, Narayanan, Mathiyazhagan
Format: Article
Language:English
Subjects:
Algae
Algae feedstock
Alkanes
Biofuel
Biogas
Biomass
Catalyst
Catalysts
Charcoal
Chemical compounds
Decomposition reactions
Depolymerization
Energy resources
Energy sources
Esters
Gas absorption
Greenhouse gases
Growth rate
Hydrothermal liquefaction
Liquefaction
Phenols
Process parameters
Raw materials
Reaction mechanisms
Reviews
Temperature requirements
Valorization
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Summary:•Conversion of algae biomass into bio-oil, biochar and biogas using hydrothermal liquefaction.•Algae is considered as a potential source due to its rapid growth and high flexibility.•The pathway of HTL involves de-polymerization, de-composition and recombination.•Carbohydrates, lipids and proteins which are the primary constituents of an algal biomass. Algae, a potential biomass feedstock with a faster growth rate and capability of greenhouse gas absorption, mitigates the limitations of the first- and second-generation feedstock in bio-oil production. hydrothermal liquefaction (HTL) is known to be an active method capable of producing substantial energy resources. In HTL, biomass undergoes thermal depolymerization in the presence of water, at around 280 °C–350 °C following subcritical and near supercritical conditions to produce chemical compounds such as alkanes, nitrogenates, esters, phenolics, etc. The primary product, “Biocrude/Bio-oil” obtained from the reaction, is identified as the essential fuel source after processing and also as a distinct value-added chemical source, along with biochar and biogas as co-products. This review outlines a range of routes available for thermochemical conversion of the algal biomass. It also provides a better understanding of the reaction mechanism like depolymerization, decomposition, and re-polymerization, operating conditions like temperature, pressure, the quantity of catalyst required, and the solvent used in the process. The review also highlights the yield achieved by altering the aforementioned parameters, comparing and presenting them as a collective result.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.122679