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Reversible CO sub(2) capture with porous polymers using the humidity swing

Several polymeric materials were prepared for reversible CO sub(2) capture. These materials contain quaternary ammonium ions and hydroxide counter ions, including polymers grafted from carbon black, crosslinked porous polymers templated by ordered colloidal crystals, and high internal phase emulsion...

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Published in:	Energy & environmental science 2013-01, Vol.6 (2), p.488-493
Main Authors:	He, Hongkun, Li, Wenwen, Zhong, Mingjiang, Konkolewicz, Dominik, Wu, Dingcai, Yaccato, Karin, Rappold, Tim, Sugar, Glenn, David, Nathaniel E, Matyjaszewski, Krzysztof
Format:	Article
Language:	English
Subjects:	Carbon capture and storage Carbon dioxide Crystals Design engineering Emulsions Humidity Polymers Swing
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container_end_page	493
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container_title	Energy & environmental science
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creator	He, Hongkun Li, Wenwen Zhong, Mingjiang Konkolewicz, Dominik Wu, Dingcai Yaccato, Karin Rappold, Tim Sugar, Glenn David, Nathaniel E Matyjaszewski, Krzysztof
description	Several polymeric materials were prepared for reversible CO sub(2) capture. These materials contain quaternary ammonium ions and hydroxide counter ions, including polymers grafted from carbon black, crosslinked porous polymers templated by ordered colloidal crystals, and high internal phase emulsion systems. The porous polymers displayed an order of magnitude improvement in the kinetics of the absorption and desorption processes and a significant improvement in the swing sizes compared to a commercially available material with similar functional groups. This work suggests a new direction for the design of porous polymeric materials for CO sub(2) air capture.
doi_str_mv	10.1039/c2ee24139k
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source	Royal Society of Chemistry
subjects	Carbon capture and storage Carbon dioxide Crystals Design engineering Emulsions Humidity Polymers Swing
title	Reversible CO sub(2) capture with porous polymers using the humidity swing
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