Abstract
Microalgae-based biomass has been extensively studied because of its potential to produce several important biochemicals, such as lipids, proteins, carbohydrates, and pigments, for the manufacturing of value-added products, such as vitamins, bioactive compounds, and antioxidants, as well as for its applications in carbon dioxide sequestration, amongst others. There is also increasing interest in microalgae as renewable feedstock for biofuel production, inspiring a new focus on future biorefineries. This paper is dedicated to an in-depth analysis of the equilibria, stability, and sensitivity of a microalgal growth model developed by Droop (1974) for nutrient-limited batch cultivation. Two equilibrium points were found: the long-term biomass production equilibrium was found to be stable, whereas the equilibrium in the absence of biomass was found to be unstable. Simulations of estimated parameters and initial conditions using literature data were performed to relate the found results to a physical context. In conclusion, an examination of the found equilibria showed that the system does not have isolated fixed points but rather has an infinite number of equilibria, depending on the values of the minimal cell quota and initial conditions of the state variables of the model. The numerical solutions of the sensitivity functions indicate that the model outputs were more sensitive, in particular, to variations in the parameters of the half saturation constant and minimal cell quota than to variations in the maximum inorganic nutrient absorption rate and maximum growth rate.
Highlights
About 90% of energy needs are met by burning fossil fuels such as natural gas and petroleum
Two equilibria were found at the stationary state of the considered model
To determine the stability of the equilibrium points v1 and v2, the Jacobian matrix of partial derivatives of the considered system is provided in Equation (8):
Summary
About 90% of energy needs are met by burning fossil fuels such as natural gas and petroleum. Microalgae-based biomass has been globally studied because it is capable of producing several important biochemicals, such as lipids, proteins, carbohydrates, and pigments, amongst others. These biochemicals are used as feedstock in the manufacturing of value-added products for human consumption and animal feed, pharmaceutics, biofertilizers, pigments and cosmetics, and for the synthesis of antimicrobial, antiviral, and antibacterial products and medical research, to provide just a few examples from a whole spectrum of possible applications [4,5]. Dynamic models are important tools for optimizing and controlling microalgae-based biomass systems at the laboratory and on large scales. Understanding the dynamic behavior of biomass can help reduce the gap between laboratory-scale observations and those at the industrial scale [5,11,12]
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