Microalgal cultivation can be used for CO2 and toxic gases mitigation from waste gas and microalgal lipids can be extracted and converted into biodiesel. Accordingly, there are multiple effects such as carbon reduction, waste remediation and biomass production in microalgae cultivation. In this study, using chemical random mutagenesis and domestication, we isolated mutant strains of microalgae Chlorella sp., which were tolerant to flue gas and biogas, respectively. The growth characterization, biomass production, lipid production and lipid composition of Chlorella sp. mutant strains aerated with different kind of gases were investigated. We also established outdoor microalgae-incorporating photobioreactor culture system with a gas cycle-switching operation, which could be continuously used as a CO2 capture model for biogas upgrading or flue gas remediation. In the study of flue gas utilization by microalgal mutant strain, Chlorella sp. MTF-15, aerated with different kind of flue gases from a steel plant, the China Steel Corporation in Taiwan were investigated. There three kind of the flue gases were generated from the coke oven (major components: 23-27% CO2, 80 ppm NOX and 90 ppm SO2), hot stove (24-28% CO2, 10 ppm NOX and 20 ppm SO2) and power plant (22-26% CO2, 30 ppm NOX and 20 ppm SO2). Growth profiles of the microalgal cultures aerated with three different kinds of flue gases were similar and show a higher growth potential at the aeration by 1/4 or 1/2 flue gas dilution ratios than that of with air. The maximum specific growth rate and lipid production of the Chlorella sp. MTF-15 aerated with flue gas from coke oven, hot stove and power plant were 0.827, 0.762 and 0.728 d-1, and 0.668, 0.961 and 0.792 g/L, respectively. The content of C16:0 + C18:1 (the suitable fatty acids for biodiesel production) of the Chlorella sp. MTF-15 cultures aerated with the flue gases was approximately 60-65%. However, C18:1 content of the lipid of Chlorella sp. MTF-15 culture aerated with power plant flue gas was significantly higher than those aerated with coke oven and hot stove flue gases. The optimal CO2 removal efficiency of coke oven, hot stove and power plant flue gas by Chlorella sp. MTF-15 cultures was around 25%, 40% and 50%, respectively. In addition, the NOX and SO2 removal efficiency of coke oven, hot stove and power plant flue gas by Chlorella sp. MTF-15 cultures were approximately 65% and 40% aerated with coke oven flue gas, and > 80% and > 90% aerated with hot stove and power plant flue gases. Those results suggest that growth potential, lipid production and fatty acid composition of the microalgal Chlorella sp. MTF-15 cultures are dependent on the composition of flue gas used and the module operation, at least including flue gas dilution, of the microalgal cultures. In the study of carbon dioxide utilization in livestock biogas, the livestock biogas was produced from anaerobic swine wastewater treatment contains high methane (CH4) but high carbon dioxide (CO2). The presence of high content of CO2, an incombustible gas, in biogas should be mitigated as high calorific value fuel gas. In this study, we isolated a biogas tolerance mutant strain of microalga, Chlorella sp. MB-9. The microalgal mutant strain, Chlorella sp. MB-9, can grow in the presence of gas containing H2S < 100 ppm, and the growth capacity of the microalgal culture aerated with 80% CH4 was approximately 70% of that of the control culture (0% CH4). In the field study of outdoor operation, the maximum growth rates of Chlorella sp. MB-9 aerated with desulfurized biogas (~20% CO2, ~70% CH4 and H2S < 100 ppm) at 0.05, 0.1, 0.2 and 0.3 vvm were 0.320, 0.311, 0.275 and 0.251 g/L/d. To upgrade biogas produced from the anaerobic digestion of swine wastewater, and outdoor photobioreactor was established. The outdoor microalgae-incorporating photobioreactor culture system with a gas cycle-switching operation could be continuously used as a CO2 capture model for biogas upgrading. Furthermore, our field study demonstrated that the efficiency of CO2 capture from biogas could be maintained at 50% on average, and the CH4 concentration in the effluent biogas from the Chlorella cultures increased from its original 70% up to 85-90%. In summary, our experimental results mentioned above confirm that Chlorella sp. MTF-15 and MB-9 can efficiently and directly utilize the CO2 in different kinds of flue gases or livestock biogas for microalgal growth, then produce biomass and lipid. In addition, the established outdoor photobioreactor system using a gas cycle-switching operation could be used as a continuously CO2 capture model for flue gas bioremediation and biogas upgrading. Those results are confirmed that the microalgae-based CO2 biological fixation is regarded as a potential way to not only reduce CO2 emission but also achieve to produce lipid-rich microalgal biomass as a regenerative energy source.