Nucleation of Porous Crystals from Ion-Paired Prenucleation Clusters

Current nucleation models propose manifold options for the formation of crystalline materials. Exploring and distinguishing between different crystallization pathways on the molecular level however remain a challenge, especially for complex porous materials. These usually consist of large unit cells...

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Veröffentlicht in:	Chemistry Of Materials 2022-06, Vol.34 (16), p.7139-7149
Hauptverfasser:	Pellens, N, Doppelhammer, Nikolaus, Radhakrishnan, Sambhu, Asselman, K, Chandrasekharan Nair, Vinodchandran, Vandenabeele, Dries, Jakoby, B, Martens, J.A, Taulelle, F, Reichel, E.K, Breynaert, E, Kirschhock, Christine
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creator	Pellens, N Doppelhammer, Nikolaus Radhakrishnan, Sambhu Asselman, K Chandrasekharan Nair, Vinodchandran Vandenabeele, Dries Jakoby, B Martens, J.A Taulelle, F Reichel, E.K Breynaert, E Kirschhock, Christine
description	Current nucleation models propose manifold options for the formation of crystalline materials. Exploring and distinguishing between different crystallization pathways on the molecular level however remain a challenge, especially for complex porous materials. These usually consist of large unit cells with an ordered framework and pore components and often nucleate in complex, multiphasic synthesis media, restricting in-depth characterization. This work shows how aluminosilicate speciation during crystallization can be documented in detail in monophasic hydrated silicate ionic liquids (HSILs). The observations reveal that zeolites can form via supramolecular organization of ion-paired prenucleation clusters, consisting of aluminosilicate anions, ion-paired to alkali cations, and imply that zeolite crystallization from HSILs can be described within the spectrum of modern nucleation theory.
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title	Nucleation of Porous Crystals from Ion-Paired Prenucleation Clusters
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