CO₂ Sequestration by Direct Aqueous Mineral Carbonation under Low-Medium Pressure Conditions

Abstract

As CO₂ is the largest contributor to the greenhouse effect, reducing the total CO₂ emissions into the atmosphere has been considered as the breakthrough point of mitigating the greenhouse effect. Mineral carbonation is a potential route for CO₂ sequestration. In this paper, the mineral carbonation reaction characteristics of wollastonite, serpentine and olivine under low-medium pressure conditions were investigated. Many tests including XRD, XRF, BET and thermal decomposition were applied. Parameters, such as reaction temperature, reaction pressure, particle size, solution composition and heat-treatment, were discussed in details. The results show that besides increase of reaction temperature and pressure, addition of NaHCO₃ and decrease of particle size can also effectively accelerate the carbonation reaction for all the three minerals. Heat-treatment of minerals is only useful for serpentine. Highest carbonation conversion efficiency of 83.5%, 47.7% and 16.9% was respectively achieved for wollastonite, serpentine and olivine under the condition of T=150°C, P=40 bar and particle sizes <30 µm. Compared the conversion efficiencies, it is indicated that wollastonite was the most reactive mineral and olivine was suggested to be not suitable for CO₂ sequestration by direct aqueous mineral carbonation under low-medium pressure conditions.