Abstract
There are many problems associated with the methods for scaling microalgae culture systems. Mathematical models - predictive models in particular - are considered key, but most of them require specialist programming and computer science skills. Even where these skills are available, new parameters (such as radiative properties for determining the effect of light attenuation on photosynthetic growth) have to be determined with each application of the model for a new strain of microalgae, and this in itself is highly complex. Consequently, the methods used in the field are still mainly (semi-)empirical. A simplified method of determining maximal performance and the corresponding optimal operating points (i.e. biomass concentration, harvesting rate) for a given culture system, strain and culture condition (including solar) is presented here. The approach involves engineering equations, which are smartly adapted in this study to eliminate parameters that are difficult to obtain, with a few conventional small-scale experiments to determine the remaining key parameters relevant to the strain. The method is applied with two strains: Haematococcus pluvialis (in green phase and under continuous light) and a Picochlorum maculatum strain isolated from the Qatar desert (in both continuous and diurnal light cycles). A deviation of <10 % was achieved between the predicted data and the experimental data. The proposed method, which eliminates several months of experiments and is relatively simple to apply, appears to be an appropriate tool for optimizing and accelerating the scaling-up of microalgae culture systems.
Original language | English |
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Article number | 103517 |
Journal | Algal Research |
Volume | 80 |
DOIs | |
Publication status | Published - Jun 2024 |
Keywords
- Maximal productivity
- Microalgae
- Optimization
- Photobioreactors
- Scaling