Increasing of carbon dioxide (CO2) concentration in the atmosphere may enhance the global warming effect. In this study, CO2 capture by accelerated carbonation of basic oxygen furnace (BOF) slag is performed under different liquid-to-solid (L/S) ratio and temperature in a slurry reactor. The BOF slag, provided by China Hi-ment Corporation, is rich in calcium content and exhibits alkaline properties, which is beneficial to carbonation reaction. The result indicated that CO2 mass balance within the slurry reactor is quite acceptable and the relative percent difference (RPD) was less than 10%, which indicated that the slurry reactor was a viable method to capture CO2 by BOF slags. The maximum carbonation conversion of BOF slag achieved was 56.99% under an L/S ratio of 20 mL/g, a CO2 flow rate of 0.1 L/min and a pressure of 101.3 kPa at 50 oC for 120 min. In addition, the reaction product was identified as calcite (CaCO3) according to the observations of SEM and XRD. Meanwhile, reaction kinetics of carbonation of BOF slag in the slurry reactor was evaluated by the shrinking core model (SCM) and surface coverage model. Based on the results of SCM, the rate-limiting step was found to be chemical reaction controlled in 20 minutes after carbonation was conducted; and then nd the diffusion provided all the extra carbonation conversion after 60 minutes. However, to define the difference between ash layer and gas film control may need to take further analysis. Effective diffusivity (De) was ranged from 1.66 x 10-6 to 1.8 x 10-6 for different temperature at L/S = 5, the range of De value up to 103 at different L/S ratio. Furthermore, the reaction rate constant (ks) was determined by the surface coverage model, which the reaction time was in a good correlation with the carbonation conversion of BOF slag. It was thus concluded that carbonation of BOF slag in a slurry reactor is a viable method for CO2 capture.