Conversion of biomass to biofuels and life cycle assessment: a review

The global energy demand is projected to rise by almost 28% by 2040 compared to current levels. Biomass is a promising energy source for producing either solid or liquid fuels. Biofuels are alternatives to fossil fuels to reduce anthropogenic greenhouse gas emissions. Nonetheless, policy decisions f...

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Bibliographic Details
Published in:Environmental chemistry letters 2021-12, Vol.19 (6), p.4075-4118
Main Authors: Osman, Ahmed I., Mehta, Neha, Elgarahy, Ahmed M., Al-Hinai, Amer, Al-Muhtaseb, Ala’a H., Rooney, David W.
Format: Article
Language:English
Subjects:
Alternative fuels
Analytical Chemistry
Anthropogenic factors
Bibliometrics
Biochemistry
Biodiesel fuels
Biofuels
Biomass
Circular economy
Combustion
Conversion
Earth and Environmental Science
Ecotoxicology
Energy demand
Energy sources
Environment
Environmental Chemistry
Environmental impact
Enzymolysis
Fermentation
Fossil fuels
Fuels
Gasification
Geochemistry
Greenhouse gases
High temperature
Human influences
Life cycle
Life cycle analysis
Life cycle assessment
Life cycles
Liquid fuels
Low temperature
Pollution
Pyrolysis
Review
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Summary:The global energy demand is projected to rise by almost 28% by 2040 compared to current levels. Biomass is a promising energy source for producing either solid or liquid fuels. Biofuels are alternatives to fossil fuels to reduce anthropogenic greenhouse gas emissions. Nonetheless, policy decisions for biofuels should be based on evidence that biofuels are produced in a sustainable manner. To this end, life cycle assessment (LCA) provides information on environmental impacts associated with biofuel production chains. Here, we review advances in biomass conversion to biofuels and their environmental impact by life cycle assessment. Processes are gasification, combustion, pyrolysis, enzymatic hydrolysis routes and fermentation. Thermochemical processes are classified into low temperature, below 300 °C, and high temperature, higher than 300 °C, i.e. gasification, combustion and pyrolysis. Pyrolysis is promising because it operates at a relatively lower temperature of up to 500 °C, compared to gasification, which operates at 800–1300 °C. We focus on 1) the drawbacks and advantages of the thermochemical and biochemical conversion routes of biomass into various fuels and the possibility of integrating these routes for better process efficiency; 2) methodological approaches and key findings from 40 LCA studies on biomass to biofuel conversion pathways published from 2019 to 2021; and 3) bibliometric trends and knowledge gaps in biomass conversion into biofuels using thermochemical and biochemical routes. The integration of hydrothermal and biochemical routes is promising for the circular economy.
ISSN:1610-3653
1610-3661
DOI:10.1007/s10311-021-01273-0