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Exploring a Novel Adsorbent for CO<sub>2</sub> Capture and Gas Separation

Jaouad Al Atrach, Abdelhafid Aitblal, Abdallah Amedlous, Edwin B. Clatworthy, Diógenes Honorato Piva, Ying Xiong, Rémy Guillet‐Nicolas, Valentin Valtchev

2025ACS Applied Materials & Interfaces18 citationsDOIOpen Access PDF

Abstract

The urgent need to mitigate carbon emissions has spurred research into small-pore zeolites as cost-effective options for CO 2 capture by solid adsorbents, particularly in postcombustion and biogas separation applications. In this study we investigate levyne (LEV-type) zeolite, a largely unexplored material for CO 2 adsorption, as a novel adsorbent for CO 2 capture and gas separation. Using seed-assisted synthesis approaches and different synthesis conditions, nanosized and micron-sized LEV zeolites were synthesized and characterized in terms of synthesis pathways, morphology, crystal size, and chemical composition. The variation of the Si/Al ratios and chemical compositions of the synthesized LEV zeolites resulted in significant differences in their CO 2 adsorption capacity and separation selectivity. Micron-sized LEV, with a lower Si/Al ratio = 3.5 and a higher Na + content, exhibited superior CO 2 uptake and stronger interactions with CO 2 than the nanosized LEV (Si/Al = 6.6). Dynamic adsorption measurements using breakthrough curve analysis revealed that the micron-sized LEV exhibited twice the CO 2 adsorption capacity of its nanosized counterpart, along with higher CO 2 /N 2 and CO 2 /CH 4 selectivities. This enhanced performance, including better cyclability, emphasizes the critical role of the zeolite Si/Al ratio in improving adsorption and separation properties. In situ FTIR measurements supported these findings, showing that the nanosized LEV predominantly adsorbs CO 2 by physisorption, allowing efficient desorption using He flow only. In contrast, micron-sized LEV primarily physisorbs CO 2 but also exhibited chemisorbed CO 2, reflective of the more highly charged framework (higher Al content) and extra-framework cation content. These results highlight the importance of synthesis strategies in optimizing the properties of LEV zeolite, making them promising candidates as physical adsorbents for gas separation applications.

Topics & Concepts

Materials scienceAdsorptionGas separationSeparation (statistics)Chemical engineeringNanotechnologyPhysical chemistryComputer scienceMembraneMachine learningBiologyEngineeringGeneticsChemistryCarbon Dioxide Capture TechnologiesMembrane Separation and Gas TransportPhase Equilibria and Thermodynamics
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