Intrinsic flexibility of the EMT zeolite framework under pressure

Antony Nearchou, Mero-Lee U. Cornelius, Jonathan Skelton, Zoe L. Jones, Andrew B. Cairns, Ines E, Collings, Paul R. Raithby, Stephen A. Wells, Asel Sartbaeva

    Research output: Contribution to journalArticlepeer-review

    Abstract

    The roles of organic additives in the assembly and crystallisation of zeolites is still not fully understood. This is important when attempting to prepare novel frameworks to produce new zeolites. We consider 18-crown-6 ether (18C6) as an additive, which has previously been shown to 18 differentiate between the EMT and FAU zeolite frameworks. However, it is unclear whether this distinction is dictated by influences on the metastable free-energy landscape or geometric templating. Using high pressure synchrotron X-ray diffraction, we have observed that the presence of 18C6 does not impact the EMT framework flexibility – agreeing with our previous geometric simulations and suggesting that 18C6 does not behave as a geometric template. This was further studied by computational modelling using solid-state density-functional theory and lattice-dynamics calculations. It is shown that the lattice energy of FAU is lower than EMT, but is strongly impacted by the presence of solvent/guest molecules in the framework. Furthermore, the EMT topology possesses a greater vibrational entropy and is stabilised by free energy at finite temperature. Overall, these findings demonstrate that the role of the 18C6 additive is to influence the free-energy of crystallisation to assemble the EMT framework as opposed to FAU.
    Original languageEnglish
    JournalMolecules
    Early online date12 Feb 2019
    DOIs
    Publication statusPublished - 2019

    Keywords

    • zeolite
    • framework materials
    • EMC-2
    • crystallisation
    • high pressure
    • X-ray diffraction
    • flexibility window
    • compressibility
    • lattice dynamics

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