This study aims to develop high-gravity technologies for carbon capture utilization and air pollutant reduction by alkaline waste by-products. High gravity technology using in carbon capture process have advantages of high mass transfer coefficient, operating in atmospheric pressure and ambient temperature, small space requirements. In the on-site experiments, high gravity technology applied to reduce CO2, NOx, SOx and particle matters simultaneously. In addition, the electric arc furnace slag (EAFS) used in carbon capture process can be reused to substitute Portland cement after stabilization. The research objectives included investigating the effects of operating conditions on the carbonization behavior of rotating packed bed (RPB): The effect of two operation parameters including rotating speed and liquid-to-solid ratio on the carbon capture capacity of EAFS were investigated for both direct and indirect carbonation processes. The results showed that rotating speed of RPB can increase reaction rate and the carbonation efficiency significantly. Several models are developed to describe the reaction kinetics and mass transfer, during the leaching and carbonation process. A shrinking core model was used to describe the leaching process of alkaline waste. process of alkaline waste. The comparison results among models showed that the process was mainly controlled by fill diffusion effect. In the carbonation process, a surface coverage model was used for the description of calcium conversion and a calcium concentration model was used for the prediction of calcium concentration in solution; the performance of high gravity technology was demonstrated on air emission control via on-site experiments: The feasibility to use stabilized electric arc furnace slag for substituting Portland cement in making concreate was investigated: Fresh EAFS and carbonated EAFS are all feasible for Portland cement substitution according to their similar constitutions with ordinary Portland cement (OPC). Besides, to ensure the safety of using such substitution materials, the process must proceed by the TCLP test. The performance test in workability, durability and compressive strength shows that carbonated EAFS has a better performance comparing with other materials. Besides, a comprehensively evaluation of the process from the perspective of environmental, economic and engineering aspects. The following optimized operation conditions were obtained by the 3E (environmental, economic and engineering) analysis for the on-site operation.