Algal nutrient solution
[2] In a unified system, algal biomass can be collected by utilizing carbon dioxide emanating from power plants and wastewater discharged by both industrial and domestic sources.
Recently, there has been an increased consideration of using photobioreactors for large-scale algal biomass production, driven by their ability to create ideal growth conditions.
[5] Raceway ponds, much like the oxidation ditches utilized in wastewater treatment systems, are expansive open basins distinguished by their shallow depths and lengths that far exceed their widths.
He advocated for the integration of algal ponds with wastewater treatment plants as a cost-effective and environmentally friendly method for nutrient removal and biomass production.
Common ways to harvest algae include using microfilters, causing particles to clump together (flocculation), allowing them to settle (sedimentation), using flotation, and employing centrifuges.
Notably, their capacity to sequester CO2 and integrate seamlessly into wastewater treatment processes enhances the sustainable energy initiative aspect.
These components can be leveraged for the production of bio-oil, bioethanol, biohydrogen, and biogas through diverse thermochemical and biochemical pathways, thereby enhancing the overall energy balance.
Algae possess significant promise due to their rapid growth rate and exceptional yield per hectare, surpassing that of land-based biomass by a considerable margin.
Unlike energy crops like oil palm and rapeseed, which have sparked sustainability concerns due to food versus fuel competition and land occupation.
Algae does not compete with crops for arable land and can utilize wastelands unsuitable for agriculture owing to their ability to adapt to harsh environments.
[6] Within aquatic ecosystems, algae assumes a pivotal role by utilizing photosynthesis to transform water and carbon dioxide into sugar, concurrently releasing oxygen as a by-product.
Although strides have been made in reducing nutrient costs by utilizing wastewater and flue gases, the expenses associated with mechanical equipment and technologies remain substantial.
Similarly, effectively utilizing chemicals, technology, electricity, and labor for microalgal biofuel production poses considerable challenges.
Cultivating microalgae in both closed and open reactors under optimal pH, temperature, and light conditions is crucial for achieving rapid biomass doubling and high productivity.
However, ensuring the availability of these nutrient sources and maintaining suitable environmental conditions amidst changing climatic patterns presents sustainability challenges.
