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The Bronsted acidity of three- and two-dimensional zeolites

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    0517552 - ÚFCH JH 2020 RIV NL eng J - Journal Article
    Ho, V. T. - Vaculík, J. - Přech, Jan - Kubů, Martin - Čejka, Jiří - Nachtigall, P. - Bulánek, R. - Grajciar, L.
    The Bronsted acidity of three- and two-dimensional zeolites.
    Microporous and Mesoporous Materials. Roč. 282, JUL 2019 (2019), s. 121-132. ISSN 1387-1811. E-ISSN 1873-3093
    R&D Projects: GA ČR GA17-01440S; GA ČR(CZ) GA17-07642S
    Grant - others:GA MŠk(CZ) LM2015042
    Institutional support: RVO:61388955
    Keywords : temperature infrared-spectroscopy * total-energy calculations * carbon-monoxide * ab-initio * surface-acidity * molecular-dynamics * hydroxyl-groups * co adsorption * p-31 nmr * sites * Bronsted acidity * Two-dimensional zeolite
    OECD category: Physical chemistry
    Impact factor: 4.551, year: 2019
    Method of publishing: Limited access

    The zeolite activity in processes driven by Bronsted acid sites is determined by the distribution of the protons in the zeolite and strength of their interaction with the framework. This study aims to assess how much the transformation from three-dimensional (3D) bulk zeolite to its corresponding two-dimensional (2D) layered form changes the proton distribution and strength of the proton-framework interaction and thus how much it affects the zeolite Bronsted acid strength. Zeolites with three distinct topologies, MWW, PCR, and MFI, which form also layered analogues with considerably different thickness and silanol density were considered. To probe the Bronsted acidity of both 3D and 2D forms, an array of typical acidity descriptors (i.e., O-H stretching frequency, shift of O-H frequencies upon adsorption of CO probe molecule, C-O stretching frequencies and adsorption enthalpies of the CO adsorption complex) have been evaluated, employing both dispersion-corrected density functional theory and Fourier-transform infrared spectroscopy. Using these descriptors, the Bronsted acidity of 2D form is, on average, the same or just slightly lower than that of the 3D form. Transformation to layered form does affect the proton distribution and values of acidity descriptors for individual T sites, however, if all T sites are considered, the aggregate effect is almost negligible. Hence, these results suggest that a larger effect of the 3D > 2D transformation can be expected for frameworks with fewer distinct T sites.
    Permanent Link: http://hdl.handle.net/11104/0302886

     
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