Encapsulated Ionic Liquids with MOF-Driven CO<sub>2</sub> Channels: Overcoming Kinetic Limits for Rapid Carbon Capture
Huachen Liu, Wenjun Zhao, Hao Lü, Hong Meng
Abstract
The urgent challenge of anthropogenic climate change has intensified demand for innovative carbon capture solutions. However, conventional CO 2 capture technologies such as adsorption, absorption, and membrane separation are limited by high energy costs and scalability limitations, which restrict their viability as future-oriented solutions. This study introduces a novel microcapsule capture system (MECS) that synergizes liquid-phase selectivity and solid-phase mass transfer efficiency, overcoming kinetic bottlenecks from the low specific surface area and high viscosity of ionic liquids. The ionic liquid [Bmim][Ac] was encapsulated within a sodium alginate gel matrix. This strategy significantly enhances the interfacial contact area with CO 2, which accelerates capture kinetics. The spatial confinement within microcapsules mitigates viscosity-induced kinetic bottlenecks that improves adsorption capacity. Further, adding a zirconium-based metal–organic framework (UiO-66-NH 2 ) into the shell creates engineered CO 2 transport channels and reduces diffusion resistance and increases the capture rate ∼5 times. Under simulated flue gas, UiO-66-NH 2 -embedded microcapsules achieved a CO 2 adsorption capacity of 1.62 mmol/g and surpassed that of pure [Bmim][Ac] (0.99 mmol/g). They demonstrated CO 2 /N 2 selectivity of 28 and exceptional mechanical resilience, withstanding loads up to 20000 times their mass. Thus, under typical industrial conditions, the microcapsules show superior stability, capture capacity, and efficiency, which makes them well-suited for large-scale carbon capture.