Tuning the Adsorption Properties of Zeolites as Adsorbents for CO sub(2) Separation: Best Compromise between the Working Capacity and Selectivity

The choice of an appropriate adsorbent for CO sub(2) separation by pressure-swing adsorption remains a field of intense research. In this work, several FAU and LTA zeolites with different Na contents (Si/Al ratios) are studied for the separation of CO sub(2) from mixtures of CO sub(2), CO, and CH su...

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Published inIndustrial & engineering chemistry research Vol. 53; no. 23; pp. 9860 - 9874-9860-9874
Main Authors Garcia, Edder J, Perez-Pellitero, Javier, Pirngruber, Gerhard D, Jallut, Christian, Palomino, Miguel, Rey, Fernando, Valencia, Susana
Format Journal Article
LanguageEnglish
Published 11.06.2014
Subjects
Adsorbents
Adsorption
Carbon dioxide
Constants
Mathematical models
Optimization
Selectivity
Separation
Zeolites
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Summary:The choice of an appropriate adsorbent for CO sub(2) separation by pressure-swing adsorption remains a field of intense research. In this work, several FAU and LTA zeolites with different Na contents (Si/Al ratios) are studied for the separation of CO sub(2) from mixtures of CO sub(2), CO, and CH sub(4) by means of breakthrough experiments. The breakthrough experiments were carried out between 1 and 5 bar at 303 K using two feed mixtures: 50/50 (v/v) CO sub(2)/CH sub(4) and 75/15/15 (v/v/v) CO sub(2)/CH sub(4)/CO. The most polar zeolites, i.e., those with high Na content, exhibit the highest adsorption capacity and selectivity for CO sub(2), but their regeneration is difficult; hence, their working capacity is low. The opposite is true for the least polar zeolites, i.e., those with low Na content. In order to quantify the trade-off between the selectivity and working capacity, the Ruthven statistical model (RSM) was used. It satisfactorily reproduced the experimental trends. We, therefore, used the RSM to identify the properties of the adsorbent that lead to an optimal compromise between the working capacity and separation factor. The critical parameter is the concentration of extraframework cations, which, in turn, depends on the framework charge of the zeolites FAU and LTA. The optimal trade-off zone is defined in terms of the Henry constant of CO sub(2) (K sub(CO) sub(2)). It is found that this zone is placed between K sub(CO) sub(2) = 5 10 super(-3) and 50 10 super(-3) molecules.bar super(-1).Aa super(-3). This interval corresponds to a heat of adsorption of CO sub(2) at zero coverage between 27 and 32 kJ.mol super(-1). In our study, this optimal range of Henry constants was achieved for the zeolites Na-USY, SAPO-37, LTA (Si/Al = 5), and EMC-1.
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ISSN:0888-5885
1520-5045
DOI:10.1021/ie500207s