Highly selective and permeable SSZ-13 zeolite membranes synthesized by a facile in-situ approach for CO2/CH4 separation

High-quality tubular SSZ-13 zeolite membranes were fabricated by a facile in-situ approach for the first time. The in-situ approach requires only a single hydrothermal step for membrane growth, which is much simpler than the normal multi-step secondary-growth approach with seed preparation and seeding steps. The proper aging time and relatively high synthesis temperature provide sufficient nuclei for SSZ-13 growth, which further facilitates the in-situ formation of continuous membranes on the substrates. Three SSZ-13 zeolite membranes fabricated by the simple in-situ approach displayed ultrahigh average selectivity of (233 +/- 46) and high average carbon dioxide permeance of (1220 +/- 100) x 10(-9) mol (m(2) s Pa)(-1) [similar to 3660 +/- 300 Gas Permeation Unit (GPU), 1 GPU = 3.348 x 10(-10) mol/(m(2) s Pa)] at 298 K in the CO2/CH4 (50/50 in mol) mixture. The overall separation performance of the current membranes exceeded that of most reported zeolite membranes in the CO2/CH4 mixture. It indicated that the current in-situ synthesis approach had good reproducibility. The typical membrane also showed excellent separation performance in the CO2/N-2 mixture toward the carbon capture from flue gas. The long-term stability of this membrane was investigated in the humidified CO2/CH4 mixture with a relative humidity close to 100%. This simple in-situ approach is suitable to prepare other zeolite membranes for gas separation after improving the gel nucleation.

Automated summary

High-quality tubular SSZ-13 zeolite membranes were successfully fabricated for the first time using a facile in-situ approach. This approach, which only requires a single hydrothermal step, is much simpler than the multi-step secondary-growth approach. The membranes exhibited excellent selectivity and permeance in gas separation, surpassing most reported zeolite membranes.