Survival of the Fittest Nanojar: Stepwise Breakdown of Polydisperse Cu27−Cu31 Nanojar Mixtures into Monodisperse Cu27(CO3) and Cu31(SO4) Nanojars

Nanojars are emerging as a class of anion sequestration agents of unparalleled efficiency. Dinegative oxoanions (e.g., carbonate, sulfate) template the formation of a series of homologous nanojars [Cu(OH)(pyrazolato)]n (n=27–31). Pyridine selectively transforms less stable, larger CO32− nanojars (n=...

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Veröffentlicht in:	Chemistry : a European journal 2016-04, Vol.22 (16), p.5499-5503
Hauptverfasser:	Ahmed, Basil M., Szymczyna, Blair R., Jianrattanasawat, Sarut, Surmann, Stuart A., Mezei, Gellert
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Sprache:	eng
Schlagworte:	anion encapsulation Chemistry copper NMR spectroscopy paramagnetism pyrazolate complexes self-assembly
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creator	Ahmed, Basil M. Szymczyna, Blair R. Jianrattanasawat, Sarut Surmann, Stuart A. Mezei, Gellert
description	Nanojars are emerging as a class of anion sequestration agents of unparalleled efficiency. Dinegative oxoanions (e.g., carbonate, sulfate) template the formation of a series of homologous nanojars [Cu(OH)(pyrazolato)]n (n=27–31). Pyridine selectively transforms less stable, larger CO32− nanojars (n=30, 31) into more stable, smaller ones (n=27, 29), but leaves all SO42− nanojars (n=27–29, 31) intact. Ammonia, in turn, transforms all less stable nanojars into the most stable one and allows the isolation of pure [CO32−⊂{Cu(OH)(pz)}27] and [SO42−⊂{Cu(OH)(pz)}31]. A comprehensive picture of the solution and solid‐state intricacies of nanojars was revealed by a combination of variable temperature NMR spectroscopy, tandem mass spectrometry, and X‐ray crystallography. Homologous nanojars based on a copper–hydroxide–pyrazolate repeating unit self‐assemble around dinegative oxoanion templates and are transformed into one single species by etching with ammonia. Tandem mass spectrometry, paramagnetic NMR, and X‐ray diffraction analyses provide a detailed picture of the solution‐ and solid‐state intricacies of this emerging anion encapsulating agent family of unparalleled binding strength (see figure).
doi_str_mv	10.1002/chem.201600271
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Dinegative oxoanions (e.g., carbonate, sulfate) template the formation of a series of homologous nanojars [Cu(OH)(pyrazolato)]n (n=27–31). Pyridine selectively transforms less stable, larger CO32− nanojars (n=30, 31) into more stable, smaller ones (n=27, 29), but leaves all SO42− nanojars (n=27–29, 31) intact. Ammonia, in turn, transforms all less stable nanojars into the most stable one and allows the isolation of pure [CO32−⊂{Cu(OH)(pz)}27] and [SO42−⊂{Cu(OH)(pz)}31]. A comprehensive picture of the solution and solid‐state intricacies of nanojars was revealed by a combination of variable temperature NMR spectroscopy, tandem mass spectrometry, and X‐ray crystallography. Homologous nanojars based on a copper–hydroxide–pyrazolate repeating unit self‐assemble around dinegative oxoanion templates and are transformed into one single species by etching with ammonia. 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Eur. J</addtitle><description>Nanojars are emerging as a class of anion sequestration agents of unparalleled efficiency. Dinegative oxoanions (e.g., carbonate, sulfate) template the formation of a series of homologous nanojars [Cu(OH)(pyrazolato)]n (n=27–31). Pyridine selectively transforms less stable, larger CO32− nanojars (n=30, 31) into more stable, smaller ones (n=27, 29), but leaves all SO42− nanojars (n=27–29, 31) intact. Ammonia, in turn, transforms all less stable nanojars into the most stable one and allows the isolation of pure [CO32−⊂{Cu(OH)(pz)}27] and [SO42−⊂{Cu(OH)(pz)}31]. A comprehensive picture of the solution and solid‐state intricacies of nanojars was revealed by a combination of variable temperature NMR spectroscopy, tandem mass spectrometry, and X‐ray crystallography. Homologous nanojars based on a copper–hydroxide–pyrazolate repeating unit self‐assemble around dinegative oxoanion templates and are transformed into one single species by etching with ammonia. 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Eur. J</addtitle><date>2016-04-11</date><risdate>2016</risdate><volume>22</volume><issue>16</issue><spage>5499</spage><epage>5503</epage><pages>5499-5503</pages><issn>0947-6539</issn><eissn>1521-3765</eissn><coden>CEUJED</coden><abstract>Nanojars are emerging as a class of anion sequestration agents of unparalleled efficiency. Dinegative oxoanions (e.g., carbonate, sulfate) template the formation of a series of homologous nanojars [Cu(OH)(pyrazolato)]n (n=27–31). Pyridine selectively transforms less stable, larger CO32− nanojars (n=30, 31) into more stable, smaller ones (n=27, 29), but leaves all SO42− nanojars (n=27–29, 31) intact. Ammonia, in turn, transforms all less stable nanojars into the most stable one and allows the isolation of pure [CO32−⊂{Cu(OH)(pz)}27] and [SO42−⊂{Cu(OH)(pz)}31]. 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subjects	anion encapsulation Chemistry copper NMR spectroscopy paramagnetism pyrazolate complexes self-assembly
title	Survival of the Fittest Nanojar: Stepwise Breakdown of Polydisperse Cu27−Cu31 Nanojar Mixtures into Monodisperse Cu27(CO3) and Cu31(SO4) Nanojars
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