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Hydrophobicity Boosts Catalytic Activity: The Tailoring of Aluminosilicates with Trimethylsilyl Groups

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    0573305 - ÚFCH JH 2024 RIV US eng J - Journal Article
    Leonova, L. - Moravec, Z. - Sazama, Petr - Pastvová, Jana - Kobera, Libor - Brus, Jiří - Stýskalík, A.
    Hydrophobicity Boosts Catalytic Activity: The Tailoring of Aluminosilicates with Trimethylsilyl Groups.
    ChemCatChem. Roč. 15, č. 13 (2023), č. článku e202300449. ISSN 1867-3880. E-ISSN 1867-3899
    R&D Projects: GA MŠMT(CZ) LM2023066; GA MŠMT(CZ) EF18_046/0015586; GA MŠMT(CZ) LM2018124
    Research Infrastructure: CIISB II - 90127
    Institutional support: RVO:61388955 ; RVO:61389013
    Keywords : acid catalysis * aluminosilicate * epoxide ring opening * ethanol dehydration * hydrophobicity
    OECD category: Physical chemistry; Polymer science (UMCH-V)
    Impact factor: 4.5, year: 2022
    Method of publishing: Open access

    Introducing organic groups into metal silicate catalysts and thus supposedly changing the surface hydrophobicity has been shown to enhance the catalyst performance in various reactions. However, the organic groups introduction does not unambiguously guarantee hydrophobicity control. Therefore, a thorough characterization is necessary to provide a complete view of the interaction between the catalyst surface, reactants, and products. Herein, an aluminosilicate catalyst with well-dispersed Al atoms was prepared via the non-hydrolytic sol-gel method. This material was post-synthetically modified with trimethylsilyl groups. Their number on the catalyst surface was controlled via a temperature-vacuum pretreatment. In such a way, aluminosilicate materials with similar porosity, structure, and acid site strength and quality were obtained. Notably, the water sorption measurements showed that trimethylsilylated aluminosilicates adsorb 2.5–3 times less water than the parent material (p/p0=0.3). The turn-over-frequency in epoxide ring opening and ethanol dehydration scaled up with the number of trimethylsilyl groups grafted on the catalyst surface. Particularly, the heavily trimethylsilylated sample achieved three to five times higher turnover-frequency in styrene oxide aminolysis than the parent aluminosilicate material. To the best of the authors’ knowledge, it exhibited the most active Al sites for epoxide aminolysis in the present literature.
    Permanent Link: https://hdl.handle.net/11104/0343769

     
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