Designing and understanding permanent microporosity in liquids

Standard microporous materials are typically crystalline solids that exhibit a regular array of cavities of uniform size and shape. Packing and directional bonding between molecular building blocks give rise to interstitial pores that confer size and shape-specific sorption properties to the materia...

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Veröffentlicht in:	Physical chemistry chemical physics : PCCP 2014-05, Vol.16 (20), p.9422-9431
Hauptverfasser:	Melaugh, Gavin, Giri, Nicola, Davidson, Christine E, James, Stuart L, Del Pópolo, Mario G
Format:	Artikel
Sprache:	eng
Schlagworte:	Arrays Computer simulation Holes Interstitials Liquids Molecular structure Porosity Sorption
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description	Standard microporous materials are typically crystalline solids that exhibit a regular array of cavities of uniform size and shape. Packing and directional bonding between molecular building blocks give rise to interstitial pores that confer size and shape-specific sorption properties to the material. In the liquid state interstitial cavities are transient. However, permanent and intrinsic "pores" can potentially be built into the structure of the molecules that constitute the liquid. With the aid of computer simulations we have designed, synthesised and characterised a series of liquids composed of hollow cage-like molecules, which are functionalised with hydrocarbon chains to make them liquid at accessible temperatures. Experiments and simulations demonstrate that chain length and size of terminal chain substituents can be used to tune, within certain margins, the permanence of intramolecular cavities in such neat liquids. Simulations identify a candidate "porous liquid" in which 30% of the cages remain empty in the liquid state. Absorbed methane molecules selectively occupy these empty cavities.
doi_str_mv	10.1039/c4cp00582a
format	Article
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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Arrays Computer simulation Holes Interstitials Liquids Molecular structure Porosity Sorption
title	Designing and understanding permanent microporosity in liquids
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