Novel mixed matrix membranes based on polymerizable room-temperature ionic liquids and SAPO-34 particles to improve CO sub(2 separation)

A mixed-matrix membrane containing three components consisting of a solid polymerized room-temperature ionic liquid (poly(RTIL)), a liquid RTIL, and a zeolite material was previously investigated. This membrane showed an improvement in CO sub(2/CH) sub(4) separation over the neat poly(RTIL)-RTIL com...

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Bibliographic Details
Published in:Journal of membrane science 2011-03, Vol.370 (1-2), p.141-148
Main Authors: Hudiono, Yeny C, Carlisle, Trevor K, LaFrate, Andrew L, Gin, Douglas L, Noble, Richard D
Format: Article
Language:English
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Summary:A mixed-matrix membrane containing three components consisting of a solid polymerized room-temperature ionic liquid (poly(RTIL)), a liquid RTIL, and a zeolite material was previously investigated. This membrane showed an improvement in CO sub(2/CH) sub(4) separation over the neat poly(RTIL)-RTIL composite membrane without the zeolite component. It was hypothesized that the RTIL served as "wetting agent," improving the adhesion between the poly(RTIL) (a charged organic polymer) and zeolite particles (charged inorganic particles). In this article, a detailed study of the CO sub(2 separation performance of this 3-component el system is presented, along with results showing how the system can be optimized or tuned. Specifically, this study focuses on the effect of varying SAPO-34 and RTIL loadings on the separation performance of the 3-component el s. 3-Component el s containing [emim][Tf) sub(2)N] and styrene-based poly(RTIL)s with various loadings of SAPO-34 and various compositions of RTILs and poly(RTIL)s were prepared. Another type of poly(RTIL), which has a longer n-alkyl substituent and a polyolefin backbone was also investigated, in addition to the initial styrene-based poly(RTIL). The single gas permeation of various compositions and types of these 3-component el s were investigated. The results show that increasing the amount of RTIL in the 3-component el increases the CO sub(2 permeability of the composite membrane. The presence of the SAPO-34 particles in the 3-component el improves both the CO) sub(2)/CH sub(4 selectivity and CO) sub(2) permeability in comparison to the neat poly(RTIL)-RTIL composite membrane. For the 3-component el s based on the poly(RTIL) with an olefin backbone, the presence of the added liquid RTIL component is not mandatory, which may be due to the similarity of its structure compared to [emim][Tf sub(2N]. In this paper, we also propose a potential molecular arrangement of the poly(RTIL), RTIL, and SAPO-34 particles in the 3-component el s.)
ISSN:0376-7388
DOI:10.1016/j.memsci.2011.01.012