(383z) Enhancing CO2 Separation Efficiency Using Chabazite-Type Zeolite Membranes: Investigating the Impact of Hydrophobicity and Defect Structure.
AIChE Annual Meeting
2024
2024 AIChE Annual Meeting
Separations Division
Poster Session: Separations Division
Tuesday, October 29, 2024 - 3:30pm to 5:00pm
Chabazite (CHA)-type zeolites offer significant potential in CO2 separation from larger molecules, with applications in post-combustion carbon capture and natural gas/biogas upgrading. Their unique pore structure, approximately 0.37 × 0.42 nm^2 in dimensions, allows for precise discrimination between CO2 (0.33 nm) and larger molecules like N2 (0.364 nm) or CH4 (0.38 nm), enabling selective separation.
The presence of siliceous constituents within CHA zeolites reduces adsorption capacity towards smaller molecules like H2O (0.265 nm), resulting in decreased H2O permeation rates. This hydrophobic nature ensures effective molecular sieving, maintaining excellent CO2 perm-selectivity even in the presence of H2O.
Experimental investigations on CHA_100 membranes with a Si/Al ratio of 100 demonstrated remarkable CO2 separation performance, particularly in the presence of H2O at 30 °C. The obtained results showed superior separation factors (SFs) for CO2/N2 (13.4) and CO2/CH4 (37) compared to dry conditions (5.2 CO2/CH4 SFs and 31 CO2/CH4 SFs, respectively). This improvement is attributed to physisorbed water molecules blocking defects.
A comprehensive quantitative analysis combining fluorescence confocal optical microscopy images and a one-dimensional permeation model revealed that approximately 19% and 20% of total CO2 permeance for CHA_100 were hindered by physisorbed water molecules and defects, respectively.
In conclusion, CHA-type zeolites show promise for efficient CO2 separation from larger molecules due to their molecular recognition capability and hydrophobic nature. Experimental results on CHA_100 membranes highlight superior CO2 separation performance, with physisorbed water molecules playing a crucial role. Quantitative analysis provides insights into transport mechanisms, aiding the development of advanced CHA zeolite membranes for CO2 separation applications.
The presence of siliceous constituents within CHA zeolites reduces adsorption capacity towards smaller molecules like H2O (0.265 nm), resulting in decreased H2O permeation rates. This hydrophobic nature ensures effective molecular sieving, maintaining excellent CO2 perm-selectivity even in the presence of H2O.
Experimental investigations on CHA_100 membranes with a Si/Al ratio of 100 demonstrated remarkable CO2 separation performance, particularly in the presence of H2O at 30 °C. The obtained results showed superior separation factors (SFs) for CO2/N2 (13.4) and CO2/CH4 (37) compared to dry conditions (5.2 CO2/CH4 SFs and 31 CO2/CH4 SFs, respectively). This improvement is attributed to physisorbed water molecules blocking defects.
A comprehensive quantitative analysis combining fluorescence confocal optical microscopy images and a one-dimensional permeation model revealed that approximately 19% and 20% of total CO2 permeance for CHA_100 were hindered by physisorbed water molecules and defects, respectively.
In conclusion, CHA-type zeolites show promise for efficient CO2 separation from larger molecules due to their molecular recognition capability and hydrophobic nature. Experimental results on CHA_100 membranes highlight superior CO2 separation performance, with physisorbed water molecules playing a crucial role. Quantitative analysis provides insights into transport mechanisms, aiding the development of advanced CHA zeolite membranes for CO2 separation applications.