Mathematical modeling of light energy flux balance in flat panel photobioreactor for Botryococcus braunii growth, CO2 biofixation and lipid production under varying light regimes

Abstract

Light is the most significant parameter for microalgal growth and light distribution inside the flat panel photobioreactor is critical to assess the photosynthetic productivity of Botryococcus braunii. In algal photobioreactors, self shading of the microalgal cells reduces the effective light penetration. The local light intensity inside the photobioreactor is essential for efficient designs. In this study B. braunii was grown in flat panel photobioreactor under varying light intensity. Maximum biomass concentration and maximum specific growth rate were 1.8 g L−1 and 1.344 d−1 respectively at light intensity of 800 μmol m−2 s−1. The maximum lipid content and lipid yield were 27.37% and 0.146 g mol photons−1 respectively at 450 μmol m−2 s−1 light intensity. The results reported in this study is used with the radiative transport equation (RTE) to accurately predict and optimize light transport in photobioreactors for biomass and lipid production. Finally, simulation of RTE in flat panel photobioreactor also suggests, at cell concentration (>0.41 g L−1) multiple scattering and diffusive reflections reduced the light penetration. Based on these results, optimal conditions for lipid production were found to be at mid level light intensity i.e. 450 μmol m−2 s−1 which allows maximizing the use of light energy by the cells to produce maximum lipid.