2018
DOI: 10.1002/cssc.201701611
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Impact of Flue Gas Compounds on Microalgae and Mechanisms for Carbon Assimilation and Utilization

Abstract: To shift the world to a more sustainable future, it is necessary to phase out the use of fossil fuels and focus on the development of low-carbon alternatives. However, this transition has been slow, so there is still a large dependence on fossil-derived power, and therefore, carbon dioxide is released continuously. Owing to the potential for assimilating and utilizing carbon dioxide to generate carbon-neutral products, such as biodiesel, the application of microalgae technology to capture CO from flue gases ha… Show more

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Cited by 107 publications
(35 citation statements)
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References 226 publications
(260 reference statements)
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“…Recently, many research studies have come up showing the positive impact of growing microalgae under high concentrations of Ci in the form of pure gaseous CO 2 , real or simulated flue gas, or soluble carbonate (bicarbonate), reporting increased carbon bio-fixation and biomass productivity (Ho et al, 2010;Sydney et al, 2010;Yoo et al, 2010;Tang et al, 2011;Singh et al, 2014;Aslam et al, 2017;Kuo et al, 2017). Detailed information can be found in elaborated reviews by Lam et al (2012); Cheah et al (2015); Thomas et al 2016; Vuppaladadiyam et al (2018). The fate of the supplied carbon can end up in making skeleton for lipids, proteins, sugars and pigments (Sydney et al, 2010).…”
Section: Co 2 Capture By Microalgaementioning
confidence: 99%
“…Recently, many research studies have come up showing the positive impact of growing microalgae under high concentrations of Ci in the form of pure gaseous CO 2 , real or simulated flue gas, or soluble carbonate (bicarbonate), reporting increased carbon bio-fixation and biomass productivity (Ho et al, 2010;Sydney et al, 2010;Yoo et al, 2010;Tang et al, 2011;Singh et al, 2014;Aslam et al, 2017;Kuo et al, 2017). Detailed information can be found in elaborated reviews by Lam et al (2012); Cheah et al (2015); Thomas et al 2016; Vuppaladadiyam et al (2018). The fate of the supplied carbon can end up in making skeleton for lipids, proteins, sugars and pigments (Sydney et al, 2010).…”
Section: Co 2 Capture By Microalgaementioning
confidence: 99%
“…Cyanobacteria offer the advantage of being able to utilize both CO 2 and bicarbonate as sources of inorganic carbon. Cost-effective means of CO 2 administration would be coupling cultivation of the cyanobacteria with waste resources such as flue gases from power plants [66], biogas from anaerobic digestion of agricultural waste [67], or biogas from aerobic composting of animal manure [68]. Inorganic carbon is also one of the greatest costs associated with scale-up for Isp production, and the CO 2 concentrations in the atmosphere (400 p.p.m.)…”
Section: Barriers To High Capacity Productionmentioning
confidence: 99%
“…[65] are too low to support high rates of growth. Cost-effective means of CO 2 administration would be coupling cultivation of the cyanobacteria with waste resources such as flue gases from power plants [66], biogas from anaerobic digestion of agricultural waste [67], or biogas from aerobic composting of animal manure [68]. The process of Isp production could thus work dually, as a means of bioremediation, preventing waste CO 2 from entering the atmosphere, and supporting high rates of cyanobacterial photosynthesis and growth.…”
Section: Barriers To High Capacity Productionmentioning
confidence: 99%
“…Algae-based biofuels have high impact, unlike the use of corn or sugarcane (Searchinger et al 2008;Chia et al 2018). Algae have potential to reduce greenhouse gases by consumption of CO 2 emitted from power plants and natural gas operations, as indicated by life-cycle assessments (Maranduba et al 2015;Vuppaladadiyam et al 2018). An advantage of using seaweed is the low lignin content which improves the enzymatic hydrolysis of cellulose.…”
Section: Introductionmentioning
confidence: 99%