CaO-Based CO2 Sorbents Effectively Stabilized by Metal Oxides

Abstract

Calcium looping (i.e., CO₂ capture by CaO) is a promising second-generation CO₂ capture technology. CaO, derived from naturally occurring limestone, offers an inexpensive solution, but due to the harsh operating conditions of the process, limestone-derived sorbents undergo a rapid capacity decay induced by the sintering of CaCO₃ . Here, we report a Pechini method to synthesize cyclically stable, CaO-based CO₂ sorbents with a high CO₂ uptake capacity. The sorbents synthesized feature compositional homogeneity in combination with a nanostructured and highly porous morphology. The presence of a single (Al₂ O₃ or Y₂ O₃ ) or bimetal oxide (Al₂ O₃ -Y₂ O₃ ) provides cyclic stability, except for MgO which undergoes a significant increase in its particle size with the cycle number. We also demonstrate a direct relationship between the CO₂ uptake and the morphology of the synthesized sorbents. After 30 cycles of calcination and carbonation, the best performing sorbent, containing an equimolar mixture of Al₂ O₃ and Y₂ O₃ , exhibits a CO₂ uptake capacity of 8.7 mmol CO₂ g^-1 sorbent, which is approximately 360 % higher than that of the reference limestone.

Keywords: CO2 sorbents; Pechini; bimetal oxide stabilizers; calcium oxide; sintering.