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Understanding CO capture kinetics and energetics by ionic liquids with molecular dynamics simulation

Room temperature ionic liquids (ILs) are recognized to be potential media for CO 2 capture, but the interaction nature is less documented which hinders the future development of ILs with high CO 2 solvation capability. Here, through all atom molecular dynamics (MD) simulations, the solvation process...

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Bibliographic Details
Published in:RSC advances 2020-04, Vol.1 (24), p.13968-13974
Main Authors: Yang, Fan, Wang, Xianjuan, Liu, Yang, Yang, Yanmei, Zhao, Mingwen, Liu, Xiangdong, Li, Weifeng
Format: Article
Language:English
Online Access:Get full text
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Summary:Room temperature ionic liquids (ILs) are recognized to be potential media for CO 2 capture, but the interaction nature is less documented which hinders the future development of ILs with high CO 2 solvation capability. Here, through all atom molecular dynamics (MD) simulations, the solvation process of CO 2 with four representative ILs, [EMIM][BF 4 ], [BMIM][BF 4 ], [EMIM]CL and [BMIM]CL was systematically studied. Our data clearly reflect the fact that hydrophobic components from both cations and anions dominate CO 2 solvation because IL-CO 2 attraction is mainly driven by the van der Waals attractions. Consequently, cations with longer alkyl chain (for instance, [BMIM] + than [EMIM] + ) and anions with higher hydrophobicity (for instance, [BF 4 ] − than CL − ) effectively enhance CO 2 solvation. For all the ILs under study, addition of water into ILs abates CO 2 solvation through regulating the anion-CO 2 interactions. Moreover, it is worth mentioning that ILs with a hydrophobic anion ([BF 4 ] − in this study) are more resistant to the existence of water to capture CO 2 than ILs with a hydrophilic anion (Cl − in this study). Free energy decomposition analyses were conducted which support the above findings consistently. Generally, it is predicted that cations with long alkyl chain, anions with high hydrophobicity, and ILs with smaller surface tension are potentially effective CO 2 capturing media. Our present study helps the deep understanding of the CO 2 capturing mechanism by ILs and is expected to facilitate the future design and fabrication of a novel IL medium for gas capture and storage. The interactions between ionic liquids (ILs) and CO 2 were studied by molecular dynamics simulations. Several key characters, including the volumes of cations and anions, the length of the alkyl chain have been assessed on CO 2 capture capability.
ISSN:2046-2069
DOI:10.1039/d0ra02221g