posted on 2016-01-27, 00:00authored byKarel
J. Hartlieb, James M. Holcroft, Peyman Z. Moghadam, Nicolaas
A. Vermeulen, Mohammed M. Algaradah, Majed S. Nassar, Youssry Y. Botros, Randall Q. Snurr, J. Fraser Stoddart
Porous
metal–organic frameworks (MOFs) have been studied
in the context of a wide variety of applications, particularly in
relation to molecular storage and separation sciences. Recently, we
reported a green, renewable
framework material composed of γ-cyclodextrin (γ-CD) and
alkali metal saltsnamely, CD-MOF. This porous material has
been shown to facilitate the separation of mixtures of alkylaromatic
compounds, including the BTEX mixture (benzene, toluene, ethylbenzene,
and the regioisomers of xylene), into their pure components, in both
the liquid and gas phases, in an energy-efficient manner which could
have implications for the petrochemical industry. Here, we report
the ability of CD-MOF to separate a wide variety of mixtures, including
ethylbenzene from styrene, haloaromatics, terpinenes, pinenes and
other chiral compounds. CD-MOF retains saturated compounds to a greater
extent than their unsaturated analogues. Also, the location of a double
bond within a molecule influences its retention within the extended
framework, as revealed in the case of the structural isomers of pinene
and terpinine, where the isomers with exocyclic double bonds are more
highly retained than those with endocyclic double bonds. The ability
of CD-MOF to separate various mono- and disubstituted haloaromatic
compounds appears to be controlled by both the size of the halogen
substituents and the strength of the noncovalent bonding interactions
between the analyte and the framework, an observation which has been
confirmed by molecular simulations. Since CD-MOF is a homochiral framework,
it is also able to resolve the enantiomers of chiral analytes, including
those of limonene and 1-phenylethanol. These findings could lead to
cheaper and easier-to-prepare stationary phases for HPLC separations
when compared with other chiral stationary phases, such as CD-bonded
silica particles.