Electrochemical technologies that involve microorganisms are considered to be promising for sustainable applications.
Microalgae can be used for carbon capture through photosynthesis which can directly fix carbon dioxide (CO2). Theconversion of CO2 in...
Electrochemical technologies that involve microorganisms are considered to be promising for sustainable applications.
Microalgae can be used for carbon capture through photosynthesis which can directly fix carbon dioxide (CO2). Theconversion of CO2 into fuel energy and other high value metabolites without pollution can contribute to reduce CO2 emissionswith more economic value. Light energy to biomass conversion efficiency is a major challenge in microalgal cultivation.
Electrode assisted cultivation techniques for improved photosynthetic and carbon (CO2) fixation metabolism for growth andbiomass productivity have rarely been explored for microalgae. Light limitation, which leads to the loss of photosyntheticefficiency that in turn leads to decreased microalgal growth, is a major problem in large scale cultivation systems. Here, wesummarise the ability of microalgae to perform extracellular electron uptake from cathode material for efficient biomassproduction and CO2 conversion. The present review provides insights into the possible development of electroactive microalgaeunder autotrophic and mixotrophic conditions for efficient CO2 conversion. Using the current knowledge of bioelectrochemistryand learning lessons from electroactive bacteria, we propose a proof of concept for electroactive microalgae and their futureapplications in CO2 sequestration.