Overview
FrançaisABSTRACT
This article takes the reader through the main challenges and possible solutions involved in producing liquid biofuels from energy reserves derived from microalgae. First, the elements needed to understand the production of these energy reserves will be introduced. The most promising cultivation processes and unit treatment operations will then be discussed. An introduction to the current biofuels market and legislation is also presented. Finally, the main sustainability and efficiency criteria guiding the development of this application are introduced and illustrated through research perspectives.
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Read the articleAUTHORS
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Vladimir HEREDIA: Post-doctoral researcher - Nantes University, Oniris, GEPEA, UMR 6144 F, Saint-Nazaire, France
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Jeremy PRUVOST: Professor at Nantes University, Director of GEPEA - Nantes University, Oniris, GEPEA, UMR 6144 F, Saint-Nazaire, France
INTRODUCTION
Two main types of liquid biofuel will be in production in 2023: biodiesel and bioethanol. Their production has increased in recent years, thanks to the use of mature technologies such as fermentation of sugar cane, beet or corn, and transesterification of waste oil, rapeseed or soya. However, the question of the raw materials used remains. The use of mass production intrinsic to the energy sector raises land-use conflicts with the production of agricultural resources for food (e.g. rapeseed and maize), as well as the risk of deforestation (e.g. oil palm). In France, since the Grenelle Environment Forum in 2009, priority has been given to so-called 2nd or 3rd generation biofuels, which differ from 1 and generation biofuels (also known as agrofuels) in that they are not produced from crops traditionally used for food. 2nd generation biofuels are gradually replacing those of the 1 era generation, and are derived from non-edible raw materials, agricultural waste or waste products such as used cooking oils and animal fats. This path is bringing undeniable progress, with the development of processes aimed at optimizing the use of bioresources (biorefinery-type approaches) and the industrial-scale implementation of circular economy principles. However, the growing demand for biofuels raises the question of their long-term supply. By 2023, for example, the supply of used vegetable oils is already under pressure. Obligations to integrate biofuels into the various transport sectors, and civil aviation in particular, will only increase these tensions due to the very high volumes involved.
Biofuels derived from microalgae fall into the category of 3rd generation biofuels. Although microalgae can be used as food, they are not considered a primary agricultural resource. They can also be grown on non-arable land
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KEYWORDS
microalgae | biofuels | biorefinery | sustainability
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Green chemistry
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Liquid biofuels from microalgae
Bibliography
- (1) - CHOI (Y.Y.), PATEL (A.K.), HONG (M.E.), CHANG (W.S.), SIM (S.J.) - Microalgae Bioenergy with Carbon Capture and Storage (BECCS): An emerging sustainable bioprocess for reduced CO 2 emission and biofuel production – - In Bioresource Technology Reports – Elsevier p. 100270 (2019) – 10.1016/j.biteb.2019.100270...
Regulations
Directive EU 2018/2001 on the promotion of the use of energy from renewable sources (recast) – (2018)
Patents
JUBEAU (S.), MONTALESCOT (V.), RINALDI (T.), RIOS (S.), MARCHAL (L.) and PRUVOST (J.) – Procédé de Récupération Des Lipides au Moyen d'un Broyeur A Billes – EP 3 156 474 A1. April 19, 2017.
Directory
GEPEA Laboratory – GEnie des Procédés Environnement – Agroalimentaire : https://www.gepea.fr/
SAVANE project (Station Autonome de Valorisation des Algues Naturelles Endogènes) : https://www.linkedin.com/company/savane-project/
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