Reprint

Microalgae Cultures: Environmental Tool and Bioenergy Source

Edited by
January 2022
190 pages
  • ISBN978-3-0365-2908-0 (Hardback)
  • ISBN978-3-0365-2909-7 (PDF)

This is a Reprint of the Special Issue Microalgae Cultures: Environmental Tool and Bioenergy Source that was published in

Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary

Microalgae have been intensively studied for CO2 capture, nutrient removal from wastewater, and biofuels production. These photosynthetic microorganisms use solar energy with efficiency ten times greater than terrestrial plants and are responsible for about 50% of the world’s oxygen production. Therefore, microalgae have been considered a sustainable solution for CO2 capture. Besides carbon, their growth also requires other macronutrients: nitrogen and phosphorus. To avoid the addition of fertilizers (increasing the production costs), these nutrients can be supplied if wastewater is used as the culture medium. The integration of biomass production with wastewater treatment enables a reduction in operational costs and the environmental impact. Microalgae are also known for their high lipid contents and high growth rates and are a promising oil source for biodiesel production.

This Special Issue Book presents the recent research activities concerning the environmental applications of microalgae and their potential for biofuels production, focusing on the main challenges for their large-scale application. Since microalgal culturing can address different environmental and non-environmental issues, the achievements from the integration of multiple microalgal applications are also considered in this Special Issue Book.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
fungi; algae; lichen; lipids; biofilm; lipid extraction; electro-Fenton reaction; cell wall disruption; microalgae; microalgae; inclined solid–liquid separator; hydrocarbon recovery; biofuel; energy balance; harvesting; cell growth; microalgae; chlorophyll; carotenoids; energetic yield; microalgae; biomass; photobioreactors; power consumption; Chlorella; power input; sustainability; lipids; temperature stress; photoinhibition; mixed culture; Lipomyces starkeyi; Chloroidium saccharophilum; Single Cell Oils (SCOs); Arundo donax; biorefinery; tubular photobioreactor; pilot-scale; operation regimes; outdoor cultivation; Nannochloropsis oceanica; docosahexaenoic acid; Schizochytrium sp.; crude glycerin; optimization; Plackett–Burman design; response surface methodology; biofuel; microfluidic; microalgae; UV mutagenesis; green alga; nutrient content; N:P ratio; salt tolerance; nutrient removal; salt content reduction; bioreactor; carbon capture; carbon dioxide; eutrophication; immobilization; latex polymers; process intensification; wastewater