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Adsorption of CO2 from Flue Gas Streams by a Highly Efficient and Stable Aminosilica Adsorbent
Three ordered mesoporous silicas (OMSs) with different pore sizes and pore architectures were prepared and modified with amine functional groups by a postgrafting method. The carbon dioxide (CO2) adsorption on these amine-modified OMSs was measured by using microbalances at 348 K, and their adsorption capacities were found to be 0.2–1.4 mmol g−1 under ambient pressure using dry 15% CO2. It was found experimentally that the CO2 adsorption capacity and adsorption rate were attributed to the density of amine groups and pore volume, respectively. A simple method is described for the production of densely anchored amine groups on a solid adsorbent invoking direct incorporation of tetraethylenepentamine onto the as-synthesized OMSs. Unlike conventional amine-modified OMSs, which typically show CO2 adsorption capacity less than 2 mmol g−1, such organic template occluded amine-OMS composites possessed remarkably high CO2 uptake of approximately 4.6 mmol g−1 at 348 K and 1 atm for a dry 15% CO2/nitrogen feed mixture. The enhancement of 8% in CO2 adsorption capacity was also observed in the presence of 10.6% water vapor. Durability tests done by cyclic adsorption-desorption revealed that these adsorbents also possess excellent stability.
Current available CO2 separation schemes for fossil fuel combustion normally invoke absorption by a liquid and are generally limited by the high capital and operation costs. Amine-modified solid sorbents are attractive for CO2 capture from flue gas streams because of the low energy consumption of the regeneration process. In this study, an easy method is developed by directly introducing tetraethylenepentamine onto the as-synthesized OMSs, which represents not only a time-saving route but also superior CO2 adsorption capacities and durability after repeated adsorption-desorption cycles, revealing some opportunities for future practical applications.
Adsorption of CO2 from Flue Gas Streams by a Highly Efficient and Stable Aminosilica Adsorbent
Three ordered mesoporous silicas (OMSs) with different pore sizes and pore architectures were prepared and modified with amine functional groups by a postgrafting method. The carbon dioxide (CO2) adsorption on these amine-modified OMSs was measured by using microbalances at 348 K, and their adsorption capacities were found to be 0.2–1.4 mmol g−1 under ambient pressure using dry 15% CO2. It was found experimentally that the CO2 adsorption capacity and adsorption rate were attributed to the density of amine groups and pore volume, respectively. A simple method is described for the production of densely anchored amine groups on a solid adsorbent invoking direct incorporation of tetraethylenepentamine onto the as-synthesized OMSs. Unlike conventional amine-modified OMSs, which typically show CO2 adsorption capacity less than 2 mmol g−1, such organic template occluded amine-OMS composites possessed remarkably high CO2 uptake of approximately 4.6 mmol g−1 at 348 K and 1 atm for a dry 15% CO2/nitrogen feed mixture. The enhancement of 8% in CO2 adsorption capacity was also observed in the presence of 10.6% water vapor. Durability tests done by cyclic adsorption-desorption revealed that these adsorbents also possess excellent stability.
Current available CO2 separation schemes for fossil fuel combustion normally invoke absorption by a liquid and are generally limited by the high capital and operation costs. Amine-modified solid sorbents are attractive for CO2 capture from flue gas streams because of the low energy consumption of the regeneration process. In this study, an easy method is developed by directly introducing tetraethylenepentamine onto the as-synthesized OMSs, which represents not only a time-saving route but also superior CO2 adsorption capacities and durability after repeated adsorption-desorption cycles, revealing some opportunities for future practical applications.
Adsorption of CO2 from Flue Gas Streams by a Highly Efficient and Stable Aminosilica Adsorbent
Liu, Shou-Heng (author) / Lin, Yuan-Chung (author) / Chien, Yi-Chi (author) / Hyu, Han-Ren (author)
Journal of the Air & Waste Management Association ; 61 ; 226-233
2011-02-01
8 pages
Article (Journal)
Electronic Resource
Unknown
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