Microalgae as photosynthetic organisms can use solar energy to convert water and carbon dioxide (CO2) into biomass. Facing the increasing concerns about global warming, the reduction of CO2 emission to acceptable levels by utilizing microalgae to consume CO2 and to produce biomass is a potential approach. Five microalgal strains, Chlorella sp., Nannochloropsis oculata, Skeletonema costatum, Isochrysis aff. galbana and Tetraselmis chui, were first used in this study. The growth potential of Chlorella sp., Nannochloropsis oculata, Skeletonema costatum, Isochrysis aff. galbana and Tetraselmis chui cultured in the f/2 medium (designed as normal cultural medium) and given air were 1.55, 1.51, 0.5, 0.72 and 0.99 d-1, respectively. Chlorella sp. and Nannochloropsis oculata were selected for the studies of CO2 reduction and biomass production. In this study, Chlorella sp. and Nannochloropsis oculata, were cultured in a closed system of photobioreactors in the semi-continuous cultivation conditions for the exploration of CO2 reduction and high-density microalgal biomass production. First, we determined the effects of cell density and CO2 concentration in airstreams on the growth of microalgae. The growth inhibition when the microalgal cells were cultured in 10 and 15% CO2 aeration could be overcome via a high density of microalga inoculum (up to 9 × 107 cells/mL) and pre-adapted culture with 2% CO2 aeration. The cultures were then transferred into a semi-continuous photobioreactor system aerated with 2, 5, 10 and 15% CO2. The profiles of growth curve of microalgal cultures aerated with different CO2 concentration were similar. Amount of CO2 reduction and CO2 reduction efficiency of the Chlorella sp. cultures in the semi-continuous cultivation (800 mL) under 2, 5, 10 and 15% CO2 aeration were 0.261, 0.316, 0.466 and 0.573 g/hr and 58, 27, 20 and 16%, respectively. The biomass production of Chlorella sp. cultures could maintain in 15% CO2 aeration although biomass productions showed a decreased trend when the cells exposed to the airstreams with rising CO2 concentration increased. A six-parallel photobioreactor system was also performed in this study, and the CO2 reduction efficiency in the system was similar to the single photobioreactor in different concentrations of CO2 aeration. Performances, including total amount of CO2 reduction and biomass production of the six-parallel photobioreactor system was also determined and the result were around 6 folds compared those in the matched single photobioreactor. And then, the effects of concentration of CO2 aeration on the biomass production and lipid accumulation of Nannochloropsis oculata in a semi-continuous culture were investigated in this study. The maximal biomass productivity in the semi-continuous system was 0.480 g/L/d with 2% CO2 aeration. Even the Nannochloropsis oculata cultured in the semi-continuous system aerated with 15% CO2, the biomass productivity could reach to 0.372 g/L/d. These results indicate that the CO2 reduction by microalgae incorporated photobioreactor could be extended to multiple parallel units of the photobioreactor for a large amount of waste gas treatment. To optimize the condition for long-term biomass yield from Chlorella sp. and Nannochloropsis oculata, these microalgae were suggested growing in the semi-continuous system aerated with 2% CO2 and operating by one-day replacement.