Carbon dioxide adsorption properties of K-Al-Fe–based oxides prepared from a porous polymer monolith template

Carbon dioxide adsorption properties of K-Al-Fe–based oxides prepared from a porous polymer monolith template

K-Al-Fe–based oxides with bimodal pores in the meso- and macro-size range were synthesized using spherical porous polymer monolith templates containing bicontinuous pore structures for use as a CO2 adsorbent. The porous K-Al-Fe–based oxides showed higher CO2 adsorption capacity than the correspondin...

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Bibliographic Details
Published in:Journal of solid state chemistry Vol. 274; pp. 75 - 80
Main Authors: Ikeue, Keita, Suzuki, Masashige, Yoshimoto, Daisuke, Usukawa, Ryutaro, Sakai, Munetoshi, Vagvala, Tarun Chand, Kalousek, Vit
Format: Journal Article
Language:English
Published: Elsevier Inc 01-06-2019
Subjects:
Adsorbent
Carbon dioxide
Polymer monolith
Porous materials
Water resistance
Polymer monolith
Adsorbent
Water resistance
Porous materials
Carbon dioxide
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Summary:K-Al-Fe–based oxides with bimodal pores in the meso- and macro-size range were synthesized using spherical porous polymer monolith templates containing bicontinuous pore structures for use as a CO2 adsorbent. The porous K-Al-Fe–based oxides showed higher CO2 adsorption capacity than the corresponding non-porous sample. Lowering the calcination temperature during porous K-Al-Fe–based oxide synthesis from 900 °C to 450 °C led to further increases in CO2 adsorption capacity. The CO2 adsorption capacity of this porous K-Al-Fe–based oxide was significantly enhanced after H2O vapor treatment. FT-IR analysis showed that the treatment allowed for the formation of an additional CO2 capture species. The improved CO2 adsorption capacity was due to the change in the adsorption mode of CO2 from the monodentate carbonate to a bicarbonate after a reaction with H2O vapor. The thermal and structural stability of the porous K-Al-Fe–based oxide was maintained even after treatment in H2O vapor. SEM images of porous K-Al-Fe−based oxide adsorbent. [Display omitted] •A CO2 adsorbent was prepared using a low-cost porous K-Al-Fe-based oxide.•The adsorbent showed high CO2 adsorption capacity and good reusability.•The CO2 capacity of the adsorbent improved after a H2O vapor treatment.
ISSN:0022-4596
1095-726X
DOI:10.1016/j.jssc.2019.03.013