Selective capture of CO2, which is essential for natural gas purification and CO 2 sequestration, has been reported in zeolites, porous membranes, and amine solutions. However, all such systems require substantial energy input for release of captured CO2, leading to low energy efficiency and high cost. A new class of materials named metal-organic frameworks (MOFs) has also been demonstrated to take up voluminous amounts of CO 2. However, these studies have been largely limited to equilibrium uptake measurements, which are a poor predictor of separation ability, rather than the more industrially relevant kinetic (dynamic) capacity. Here carbon dioxide capture ͉ dynamic adsorption ͉ reticular chemistry S elective removal of CO 2 from gaseous mixtures is of paramount importance for the purification of fuel gases such as methane and acetylene and because of the imminent problem of anthropogenic CO 2 emissions. Effective systems for CO 2 removal must combine high selectivity and capacity with minimal energetic input to liberate the captured CO 2 . Materials presently used are amine solutions, zeolites, and porous membranes, but all fall short in one or more of these categories (1). To date, metal-organic frameworks (MOFs) have been shown to exhibit exceptional CO 2 storage capacity under equilibrium conditions where pure CO 2 is introduced into the pores (2-6). However, their capacities are dramatically reduced when exposed to mixtures of gases under dynamic conditions, as would be the case in power plant f lue gas and methane mining applications. A useful measure of dynamic separation capacity is obtained by exposing the material to mixed gas streams and detecting the appearance or ''breakthrough'' of CO 2 from the material. Here, we report that a MOF replete with open magnesium sites, Mg-MOF-74 [Mg 2 (DOT); DOT: 2,5-dioxidoterephthalate], has excellent selectivity, facile regeneration, and among the highest dynamic capacities reported for CO 2 in porous materials. Specifically, when Mg-MOF-74 is subjected to a gas stream containing 20% CO 2 in CH 4 , a percentage in the range relevant to industrial separations, it captures only CO 2 and not CH 4 . The pores retain 89 g of CO 2 per kilogram of material before breakthrough, a value higher than any other achieved in MOFs, and that rivals the highest capacities in zeolites. Remarkably, 87% of the captured CO 2 can be liberated at room temperature, and the remaining amount can be completely removed by mild heating (80°C). Based on this favorable performance, we assert that MOFs represent a competitive class of materials for efficient CO 2 capture, and that Mg-MOF-74 strikes the right balance between high capacity and heat of adsorption, notwithstanding the great opportunities available for functionalizing such MOFs for even further improved performance.In previous work, it has been shown that coordinatively unsaturated (open) metal sites in MOFs can be prepared by removal of coordinated solvent molecules (7,8). Whereas f lexible molecular or polymeric structures rearran...
