Carbon dioxide capture in gallate-based metal-organic frameworks

Carbon capture and sequestration are vital industrial processes that not only mitigate the greenhouse effect but also promote upgrading of low-quality natural gas. Porous adsorbent-based adsorption separation process appeals to be promising, while it still remains a great challenge to develop adsorbents with high adsorption uptake and selectivity of CO2 as well as high working capacity in practical applications. In this work, a group of gallatebased metal-organic frameworks with aperture size of 3.52 to 3.65 angstrom were reported for molecular sieving of CO2 from N-2 and CH4. Remarkably, Mg-gallate exhibited a record-high uptake of CO2 (5.05 mmol g(-1)) among all reported molecular sieving adsorbents combined with ultrahigh uptake ratio of CO2/CH4 (29.7) and CO2/N-2 (84.2) at 1 bar and 298 K. Multiple O-H center dot center dot center dot C and O center dot center dot center dot H-O interactions afford dense packing of CO2 molecules in the framework structure with a density up to 1.06 g cm(-3) on Mg-gallate, verified by density function theory calculations. Experimental breakthrough experiments confirmed the superb separation performance of flue gas and natural gas over a wide range of temperature. Robust structure and cycling stability along with facile scaleup synthesis method further offer great potential of M-gallate in industrial applications.

Automated summary

This study reports a gallate-based metal-organic framework adsorbent with high CO2 adsorption uptake and selectivity. The adsorbent shows excellent performance in separating flue gas and natural gas, and exhibits robust structure and stability.