Aliyah Fakim scite author profile

Developing the competence of molecular sorbents for energy‐saving applications, such as C8 separations, requires efficient, stable, scalable, and easily recyclable materials that can readily transition to commercial implementation. Herein, we report an azobenzene‐based cage for the selective separation of p‐xylene isomer across a range of C8 isomers in both vapor and liquid states with selectivity that is higher than the reported all‐organic sorbents. The crystal structure shows non‐porous cages that are separated by p‐xylene molecules through selective CH–π interactions between the azo bonds and the methyl hydrogen atoms of the xylene molecules. This cage is stable in solution and can be regenerated directly under vacuum to be used in multiple cycles. We envisage that this work will promote the investigation of the azo bond as well as guest‐induced crystal‐to‐crystal phase transition in non‐porous organic solids for energy‐intensive separations.

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Xylene isomer separations by intrinsically porous molecular materials

Zhang

Ding

Hashem

et al. 2021

Cell Reports Physical Science

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In situ assembled ZIF superstructures via an emulsion-free soft-templating approach

et al. 2020

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A Polymorphic Azobenzene Cage for Energy‐Efficient and Highly Selective p‐Xylene Separation

et al. 2020

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Cover Picture: A Polymorphic Azobenzene Cage for Energy‐Efficient and Highly Selective p‐Xylene Separation (Angew. Chem. Int. Ed. 48/2020)

et al. 2020

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A stable and recyclable non‐porous azobenzene‐based organic cage (AZO‐Cage) that exhibits exclusive selectivity towards p‐xylene (pX) compared to all C8 isomers is reported by N. M. Khashab and co‐workers in their Communication on page 21367. This AZO‐Cage undergoes a crystal‐to‐crystal phase transition selectively in the presence of pX in both the liquid and vapor phase, which makes this platform ideal for eventual translation for the separation of high‐value benzene derivatives. The cover image illustrates the host cage crystal transition in the presence of pX guest molecules.

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Aliyah Fakim

A Polymorphic Azobenzene Cage for Energy‐Efficient and Highly Selective p‐Xylene Separation

Xylene isomer separations by intrinsically porous molecular materials

In situ assembled ZIF superstructures via an emulsion-free soft-templating approach

A Polymorphic Azobenzene Cage for Energy‐Efficient and Highly Selective p‐Xylene Separation

Cover Picture: A Polymorphic Azobenzene Cage for Energy‐Efficient and Highly Selective p‐Xylene Separation (Angew. Chem. Int. Ed. 48/2020)

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