International audienceMicroalgae are considered as one of the potential major source of biofuel for the future. However, their environmental benefit is still unclear and many scientific publications provide contradictory results. Here we perform the Life Cycle Assessment of the production and combustion of 1 MJ of algal methylester. The system under consideration uses standard open raceways under greenhouses. Lipid extraction and transesterification are carried out on a humid paste produced by centrifugation. Our environmental and energetic analysis shows that improving the energy balance is clearly the key priority to make microalgal cultivation sustainable and to reduce its greenhouse gas (GHG) emissions. To achieve significant reduction of the GHG emissions, most of the studies of the literature focus on technological breakthroughs, especially at the production step. However, since a large fraction of environmental impacts and especially GHG emissions do not occur directly at the production facility but stem from the production of the electricity required for producing, harvesting and transforming algae, it seems relevant to question the source of electricity as well as algae production technology. We consider a scenario where up to 45% of electricity was produced by a local renewable source and then we compare it to the improvements resulting from technological breakthroughs resulting in higher microalgal productivity or biomass concentration. It turns out that increasing the yield only drastically reduces the climate change for low starting productivity. The climate change is always significantly reduced by the use of local renewable electricity. It is therefore wiser to increase biomass productivity to easily achievable values (10–15 gm−2 d−1), and then radically change improvements pathways by considering the composition of the electricity mix used for example. At least, it must be underlined that the introduction of renewable electricity also affect energetic efficiency, leading to a positive cumulative energy balance due to better energetic ratios
International audienceVertical flat-panel photobioreactors for microalgae culture can be integrated into building facades. On topof providing the large solar illuminated surfaces needed for microalgae production, this original combinationopens various optimization opportunities, such as the possibility to create mutual benefits forboth systems with appropriate and efficient integration. For example, microalgal photosynthesis canbe used to fix the CO2 contained in flue gas emitted from the building (in a factory set-up) or to significantlyreduce energy consumption for thermal regulation of both photobioreactors and building.Here we report the results of a theoretical modelling-based investigation designed to define how thespecific building integration conditions affect photobioreactor operation. Expected biomass productionand light attenuation conditions encountered in the culture volume were determined for the greenmicroalgae Chlorella vulgaris for a location based in Nantes (France). Results were compared to figuresfrom the more conventional systems such as horizontal or ideally-inclined microalgal culture systems.We conclude with an energetic analysis that underlines the relevance of optimizing thermal exchangesbetween microalgal culture and building
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