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Magnesia-Stabilized Calcium Oxide Absorbents with Improved Durability for High Temperature CO2 Capture

Calcium oxide based materials are attractive regenerable absorbents for separating CO2 from hot gas streams because of their high reactivity, high CO2 capacity, and low material cost. Their high carbonation temperature makes it possible to recover and use high quality heat released during CO2 captur...

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Published in:	Industrial & engineering chemistry research 2009-12, Vol.48 (23), p.10604-10613
Main Authors:	Li, Liyu, King, David L, Nie, Zimin, Howard, Chris
Format:	Article
Language:	English
Subjects:	Applied sciences Chemical engineering Exact sciences and technology Separations
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container_issue	23
container_start_page	10604
container_title	Industrial & engineering chemistry research
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creator	Li, Liyu King, David L Nie, Zimin Howard, Chris
description	Calcium oxide based materials are attractive regenerable absorbents for separating CO2 from hot gas streams because of their high reactivity, high CO2 capacity, and low material cost. Their high carbonation temperature makes it possible to recover and use high quality heat released during CO2 capture, which increases overall process efficiency. However, the performance of all reported CaO-based absorbents deteriorates as the number of carbonation−decarbonation cycles increases. This is caused by absorbent sintering during the highly exothermic carbonation process. We have found that sintering can be effectively mitigated by properly mixing with a modest amount of MgO. A class of CaO-based absorbents with improved durability and CO2 reactivity were prepared by physical mixing of Ca(CH3COO)2 with small MgO particles followed by high temperature calcination. With 26 wt % MgO content, a CaO−MgO mixture prepared by this method gives as high as 53 wt % CO2 capacity after 50 carbonation−decarbonation cycles at 758 °C. Without MgO addition, the CO2 capacity of pure CaO obtained from the same source decreases from 66 wt % for the first cycle to 26 wt % for the 50th cycle under the same test conditions.
doi_str_mv	10.1021/ie901166b
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Their high carbonation temperature makes it possible to recover and use high quality heat released during CO2 capture, which increases overall process efficiency. However, the performance of all reported CaO-based absorbents deteriorates as the number of carbonation−decarbonation cycles increases. This is caused by absorbent sintering during the highly exothermic carbonation process. We have found that sintering can be effectively mitigated by properly mixing with a modest amount of MgO. A class of CaO-based absorbents with improved durability and CO2 reactivity were prepared by physical mixing of Ca(CH3COO)2 with small MgO particles followed by high temperature calcination. With 26 wt % MgO content, a CaO−MgO mixture prepared by this method gives as high as 53 wt % CO2 capacity after 50 carbonation−decarbonation cycles at 758 °C. 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A class of CaO-based absorbents with improved durability and CO2 reactivity were prepared by physical mixing of Ca(CH3COO)2 with small MgO particles followed by high temperature calcination. With 26 wt % MgO content, a CaO−MgO mixture prepared by this method gives as high as 53 wt % CO2 capacity after 50 carbonation−decarbonation cycles at 758 °C. Without MgO addition, the CO2 capacity of pure CaO obtained from the same source decreases from 66 wt % for the first cycle to 26 wt % for the 50th cycle under the same test conditions.</abstract><cop>Washington, DC</cop><pub>American Chemical Society</pub><doi>10.1021/ie901166b</doi><tpages>10</tpages></addata></record>
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source	American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list)
subjects	Applied sciences Chemical engineering Exact sciences and technology Separations
title	Magnesia-Stabilized Calcium Oxide Absorbents with Improved Durability for High Temperature CO2 Capture
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