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01-05-2023 | ENVIRONMENTAL PROTECTION

Effectiveness of CO₂ Capture by Arthrospira platensis Microalgae from a Mixture Simulating Flue Gases

Authors: M. S. Vlaskin, S. V. Kiseleva, N. I. Chernova, A. V. Grigorenko, K. G. Ryndin, O. S. Popel’, S. Ya. Malanii, O. V. Slavkina, F. de Farias Naves, V. Kumar

Published in: Thermal Engineering | Issue 5/2023

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Abstract

Decarbonization of the power industry requires the search of methods for cutting down the greenhouse gas emissions into the environment, including utilization of carbon dioxide generated during combustion of hydrocarbon fuels at power facilities. One of the promising methods is the capture of carbon dioxide by biota, not only by terrestrial plants but also by aquatic organisms, including specially cultivated microalgae. In this work, the efficiency of the capture of carbon dioxide with a concentration of approximately 6% from a gas–air mixture by Arthrospira platensis (Nordst.) Geitl microalgae was studied. This concentration has been selected on the basis of experimentally determining the CO₂ content in flue gases formed at industrial gas-piston power plants. The experiments were performed using a closed photobioreactor with a capacity of 100 dm³ installed in a gas chamber enabling elevated СО₂ concentrations in an air–gas environment to be created. The maximum growth rate of the microalgae biomass is 0.140 g/(dm³ day). The effectiveness of CO₂ capture by microalgae was 0.220 g/(dm³ day) based on the results of determination of the microalgae productivity by biomass and 0.235 g/(dm³ day) based on the results of direct measurement of СО₂ concentration in the chamber. The concentration of the main nutrients (such as bicarbonates, phosphates, and nitrates) in the medium decreased by 25–50% during the experiment period. A comparative analysis of the consumption of carbon-containing components of the medium (\({\text{HCO}}_{3}^{ - },\) \({\text{CO}}_{3}^{{2 - }}\)) by microalgae during the bubbling of cultural liquids with a gas–air mixture with different carbon dioxide content was performed. In general, good viability of A. platensis microalgae (high quality of biomass and high rate of its growth) was demonstrated when it was cultivated in an atmosphere with a high concentration (6%) of CO₂.

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Title: Effectiveness of CO2 Capture by Arthrospira platensis Microalgae from a Mixture Simulating Flue Gases
Authors: M. S. Vlaskin
S. V. Kiseleva
N. I. Chernova
A. V. Grigorenko
K. G. Ryndin
O. S. Popel’
S. Ya. Malanii
O. V. Slavkina
F. de Farias Naves
V. Kumar
Publication date: 01-05-2023
Publisher: Pleiades Publishing
Published in: Thermal Engineering / Issue 5/2023
Print ISSN: 0040-6015
Electronic ISSN: 1555-6301
DOI: https://doi.org/10.1134/S0040601523050075

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