Litcius/Paper detail

Optimization of microalgae cultivation and CO2 capture in a three-stage bubble column photobioreactor: Evaluation of control strategies

Emmanuel Yahaya, Wan Sieng Yeo, Jobrun Nandong

2025Process Safety and Environmental Protection20 citationsDOIOpen Access PDF

Abstract

Global energy consumption is rising and worries about the depletion of fossil fuels and unchecked carbon dioxide (CO 2 ) emissions make the switch to sustainable energy sources urgent. Due to their fast growth rates with high CO 2 fixation, efficient nutrient removal from wastewater such as palm oil mill effluent, and lower cultivation area needs compared to traditional energy crops, microalgae, known for their adaptability, present a viable renewable energy alternative. To maximize microalgae growth in a photobioreactor system and specifically target the capture of high CO 2 emissions from waste flue gases in the palm oil industry, this study focuses on evaluating Proportional-integral (PI) control strategies for such a purpose. The results show that algal productivity and CO 2 capture efficiency depend critically on flue gas flow rate, CO 2 inflow molar percentage, and higher dissolved oxygen (DO) levels. The hindering factors on algae growth are the elevated DO levels, highlighting the necessity of an efficient control strategy to reduce the generated DO in the medium. One such strategy's implementation resulted in up to 75 % CO 2 capture efficiency, or a 2 % CO 2 molar fraction in the headspace, along with significant algal growth and specific productivity, suggesting possible uses in the generation of biodiesel or biobutanol. The microalgae-specific productivity and the carbon capture efficiency were better balanced by including control techniques to lower DO levels. The study highlighted the importance of creating customized control systems to maximize the delicate opposing trends between CO 2 capture and microalgae production in sustainable energy applications. • Exploring controller strategies to cultivate microalgae in PBR using POME. • Assessing effectiveness control strategy for carbon capture and algal productivity. • Connecting environmental conditions to CO 2 capture efficiency and algae growth.

Topics & Concepts

PhotobioreactorColumn (typography)Stage (stratigraphy)Environmental scienceBubbleProcess engineeringWaste managementEngineeringBiologyMechanical engineeringBiofuelMechanicsPhysicsPaleontologyConnection (principal bundle)Algal biology and biofuel production