Potassium-based sorbents using mesostructured γ-alumina supports for low temperature CO2 capture

In this work, a series of mesoporous alumina materials exhibiting high surface areas have been synthesized, characterized and used in the preparation of CO2 sorbents. The mesostructured powders were prepared through a soft chemistry route, employing aluminum tri-sec-butoxide-derived sol precursors i...

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Veröffentlicht in:	Ceramics international 2015-03, Vol.41 (2), p.3036-3044
Hauptverfasser:	Durán-Guevara, M.B., Ortiz-Landeros, J., Pfeiffer, H., Espitia-Cabrera, M.I., Contreras-García, M.E.
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Sprache:	eng
Schlagworte:	Aluminum Aluminum oxide Carbon capture and storage Carbon dioxide CO2 capture Inclusions Potassium Potassium carbonate Solid sorbent Sorbents Surface area Surfactants
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container_title	Ceramics international
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creator	Durán-Guevara, M.B. Ortiz-Landeros, J. Pfeiffer, H. Espitia-Cabrera, M.I. Contreras-García, M.E.
description	In this work, a series of mesoporous alumina materials exhibiting high surface areas have been synthesized, characterized and used in the preparation of CO2 sorbents. The mesostructured powders were prepared through a soft chemistry route, employing aluminum tri-sec-butoxide-derived sol precursors in the presence of different surfactants. Structural and microstructural characterization techniques showed that γ-Al2O3 powders were composed of nanocrystals, and the samples presented high surface area values (238.6–496.7m2g−1) produced by a high mesostructured order, depending on the surfactant used as structure-directing agent. Based on the textural features, selected γ-Al2O3 materials were employed as supports for the preparation of potassium-based sorbents for CO2 capture at low temperatures (30–80°C). Potassium-loaded alumina supports were synthesized by a wet impregnation method, and the CO2 sorption tests were conducted via thermogravimetric analysis. The surface area and pore volume of the potassium-impregnated supports experienced a noticeable reduction, in comparison with the original values, suggesting the inclusion of potassium inside the support porosity. Nevertheless, the sorbents showed excellent reactivity; in fact, the potassium/γ-Al2O3 sorbent prepared with 40wt% potassium content had a maximum CO2 capture capacity of 4.03mmol CO2/g sorbent at the relatively low temperature of 80°C in the presence of water vapor. These results suggest that both the potassium content and textural properties of mesostructured γ-Al2O3 supports could provide an enhancement of the CO2 absorption properties.
doi_str_mv	10.1016/j.ceramint.2014.10.140
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The surface area and pore volume of the potassium-impregnated supports experienced a noticeable reduction, in comparison with the original values, suggesting the inclusion of potassium inside the support porosity. Nevertheless, the sorbents showed excellent reactivity; in fact, the potassium/γ-Al2O3 sorbent prepared with 40wt% potassium content had a maximum CO2 capture capacity of 4.03mmol CO2/g sorbent at the relatively low temperature of 80°C in the presence of water vapor. 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The surface area and pore volume of the potassium-impregnated supports experienced a noticeable reduction, in comparison with the original values, suggesting the inclusion of potassium inside the support porosity. Nevertheless, the sorbents showed excellent reactivity; in fact, the potassium/γ-Al2O3 sorbent prepared with 40wt% potassium content had a maximum CO2 capture capacity of 4.03mmol CO2/g sorbent at the relatively low temperature of 80°C in the presence of water vapor. 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The mesostructured powders were prepared through a soft chemistry route, employing aluminum tri-sec-butoxide-derived sol precursors in the presence of different surfactants. Structural and microstructural characterization techniques showed that γ-Al2O3 powders were composed of nanocrystals, and the samples presented high surface area values (238.6–496.7m2g−1) produced by a high mesostructured order, depending on the surfactant used as structure-directing agent. Based on the textural features, selected γ-Al2O3 materials were employed as supports for the preparation of potassium-based sorbents for CO2 capture at low temperatures (30–80°C). Potassium-loaded alumina supports were synthesized by a wet impregnation method, and the CO2 sorption tests were conducted via thermogravimetric analysis. The surface area and pore volume of the potassium-impregnated supports experienced a noticeable reduction, in comparison with the original values, suggesting the inclusion of potassium inside the support porosity. Nevertheless, the sorbents showed excellent reactivity; in fact, the potassium/γ-Al2O3 sorbent prepared with 40wt% potassium content had a maximum CO2 capture capacity of 4.03mmol CO2/g sorbent at the relatively low temperature of 80°C in the presence of water vapor. These results suggest that both the potassium content and textural properties of mesostructured γ-Al2O3 supports could provide an enhancement of the CO2 absorption properties.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.ceramint.2014.10.140</doi><tpages>9</tpages></addata></record>
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subjects	Aluminum Aluminum oxide Carbon capture and storage Carbon dioxide CO2 capture Inclusions Potassium Potassium carbonate Solid sorbent Sorbents Surface area Surfactants
title	Potassium-based sorbents using mesostructured γ-alumina supports for low temperature CO2 capture
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