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Easily-prepared Hydroxy-containing Receptors Recognize Anions in Aqueous Media

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Authors

Morshedi, Mahbod
Thomas, Michael
White, Nicholas
Boer, Stephanie

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Wiley-VCH Verlag GMBH

Abstract

Despite their ready availability, O−H groups have received relatively little attention as anion recognition motifs. Here, we report two simple hydroxy‐containing anion receptors that are prepared in two facile steps followed by anion exchange, without the need for chromatographic purification at any stage. These receptors contain a pyridinium bis(amide) motif as well as hydroxyphenyl groups, and bind mono‐ and divalent anions in 9:1 CD3CN:D2O, showing a selectivity preference for sulfate. Notably, a “model” receptor that does not contain hydroxy groups shows only very weak sulfate binding in this competitive solvent mixture. In the solid state, X‐ray crystallographic studies show that the receptors tend to form extended assemblies with anions; however, 1H and DOSY NMR studies as well as molecular dynamics simulations show that only 1:1 complexes are present in solution. Molecular dynamics simulations suggest that one of the receptors suffers from competing intramolecular hydrogen bonding, while another binds partially‐hydrated anions, with the receptor's O−H groups forming hydrogen bonds to water molecules within the anion's coordination sphere.

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Chemistry - An Asian Journal

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Open Access

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Restricted until

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