Flexible Template-Free RHO Nanosized Zeolite for Selective CO2 Adsorption

Flexible small-pore zeolites are interesting candidates for flue and natural gas processing due to their high sorption capacity and selectivity. It is generally accepted that their high CO2/CH4 selectivity is due to cation gating behavior such as the “trapdoor” effect or cation-controlled molecular...

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Published inChemistry of materials Vol. 32; no. 14; pp. 5985 - 5993
Main Authors Grand, Julien, Barrier, Nicolas, Debost, Maxime, Clatworthy, Edwin B, Laine, Fabien, Boullay, Philippe, Nesterenko, Nikolai, Dath, Jean-Pierre, Gilson, Jean-Pierre, Mintova, Svetlana
Format Journal Article
LanguageEnglish
Published American Chemical Society 28.07.2020
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Summary:Flexible small-pore zeolites are interesting candidates for flue and natural gas processing due to their high sorption capacity and selectivity. It is generally accepted that their high CO2/CH4 selectivity is due to cation gating behavior such as the “trapdoor” effect or cation-controlled molecular sieving. Herein, nanosized RHO-type zeolite containing only inorganic cations (Na+ and Cs+) has been prepared from a colloidal precursor suspension at 90 °C for 1 h without the use of expensive organic structure directing agents. The high Cs content significantly improved the thermal stability of the RHO nanocrystals up to 550 °C. The flexibility of the RHO cages upon water adsorption/desorption is demonstrated. The dehydration of the nanosized RHO zeolite resulted in two dehydrated RHO phases, the first one presents an enlargement of the cubic unit cell and a transformation from distorted to the more regular d8r units, and the second one presents a reduction of the cubic unit cell and an increase of the distortion of the d8r units. The 8-rings elliptical distortions of the as-synthesized RHO (hydrated form) of 1.87 Å changed to 0.94 and 2.16 Å for the two dehydrated RHO forms. The flexibility of the nanosized RHO zeolite is due to the ability of the Cs+ cation to displace out from and into the D8R window sites which is of great importance for controlling the selective adsorption capacity of the RHO zeolite. The flexible RHO-type nanosized zeolite exhibited great selectivity toward CO2 over CH4. The adsorption capacity is retained after 10 cycles of CO2 adsorption/desorption and the crystalline structure is fully preserved.
ISSN:0897-4756
1520-5002
DOI:10.1021/acs.chemmater.0c01016