Advancements and Prospects in Algal Biofuel Production: A Comprehensive Review
Abstract
:1. Introduction
2. Cultivation and Harvesting of Microalgae for Production of Algae Biofuel
2.1. Cultivation Systems for Microalgae-Based Biofuel Production
2.2. Cultivation Modes for Enhanced Microalgae Biomass and Biodiesel Production
2.3. Wastewater-Based Microalgae Cultivation: Achieving Dual Benefits
2.4. Harvesting
3. Lipid Productivity and Fatty Acid Composition
3.1. Fatty Acid Composition of Microalgae as the Important Property of Biodiesel Feedstock
3.2. Enhancing Lipid Productivity in Microalgae through Various Manipulation Techniques
3.2.1. Nutrient Stress as an Approach to Enhance Lipid Content in Microalgae
3.2.2. Salinity Stress as an Approach to Enhance Lipid Content in Microalgae
3.2.3. CO2 Manipulation as an Approach to Enhance Lipid Content in Microalgae
3.2.4. Genome-Editing Techniques as an Approach to Improve Enhance Lipid Content and Biomass in Microalgae
4. Physicochemical Properties of Algae Biodiesel
4.1. Kinematic Viscosity
4.2. Surface Tension
5. Microalgae as the Sustainable Feedstock for Sustainable Aviation Fuel and Biohydrogen
5.1. Biodiesel and Sustainable Aviation Fuel
5.2. Biohydrogen
6. Conclusions and Perspectives
- Cultivation Optimization: Tailoring microalgal cultivation conditions to optimize the production of desirable fatty acids can enhance fuel properties, while genetic engineering technologies such as CRISPR/Cas9 offer precision in modifying lipid biosynthetic pathways for higher yields and better fuel characteristics. Employing hybrid cultivation systems to balance cost and productivity can also optimize resource use.
- Advanced Harvesting Techniques: Developing energy-efficient harvesting methods, such as enhanced flocculation, co-cultivation with other microorganisms, and the use of biofilm reactors to reduce costs.
- Resource Efficiency: Integrating microalgae cultivation with wastewater treatment facilities to maximize the use of nutrient-dense waste streams, hence decreasing operational expenses and overall environmental footprint.
- Policy Support and Incentives: Government subsidies, tax incentives, and other financial support are essential to making SAF from microalgae commercially viable. Most bio-jet fuel production technologies incur costs that are at least 120% higher than conventional fossil-based jet fuel, while achieving emissions reductions of at least 27%. Despite these high costs, only 38% of existing policies provide monetary incentives to SAF producers, resulting in SAF production operating at only 3.5% of its total potential capacity [160].
- Genetic Modifications: Enhancing microalgal strains through genetic engineering to increase hydrogenase activity and overall hydrogen yield.
- Bioreactor Design: Developing advanced bioreactors that maximize sunlight capture and gas exchange and optimize growth conditions.
- Integration with Waste Treatment: Using wastewater as a nutrient source for microalgae cultivation can provide a low-cost substrate while treating the wastewater, thus achieving dual benefits.
- Integration of Biohydrogen Production Into Microgrids: Implementing biohydrogen production facilities within microgrids can significantly benefit rural and remote areas. By utilizing local biomass waste residues and cultivating microalgae biomass in wastewater treatment facilities, these regions can enhance their energy independence and sustainability. In an ideal scenario, microgrids powered by green hydrogen derived from biohydrogen may offer advantages over those using electrolytically produced hydrogen.
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Falfushynska, H. Advancements and Prospects in Algal Biofuel Production: A Comprehensive Review. Phycology 2024, 4, 548-575. https://doi.org/10.3390/phycology4040030
Falfushynska H. Advancements and Prospects in Algal Biofuel Production: A Comprehensive Review. Phycology. 2024; 4(4):548-575. https://doi.org/10.3390/phycology4040030
Chicago/Turabian StyleFalfushynska, Halina. 2024. "Advancements and Prospects in Algal Biofuel Production: A Comprehensive Review" Phycology 4, no. 4: 548-575. https://doi.org/10.3390/phycology4040030