Environmentally Friendly Synthesis and Self‐Catalytic Hydrolysis of Triazole‐Modified Organosilanes for Polysiloxane Production

Author:

Aristova Vasilissa A.12,Bezlepkina Kseniya A.13ORCID,Klokova Kseniia S.1ORCID,Ardabevskaia Sofia N.13ORCID,Drozdov Fedor V.134ORCID,Cherkaev Georgij V.1,Milenin Sergey A.13ORCID

Affiliation:

1. Enikolopov Institute of Synthetic Polymeric Materials of Russian Academy of Sciences 117393 Moscow Russian Federation

2. Mendeleev University of Chemical Technology of Russia 125047 Moscow Russia

3. Research Laboratory of New Silicone Materials and Technologies Tula State Lev Tolstoy Pedagogical University 300026 Tula Russia

4. BMSTU Center of National Technology Initiative (NTI) “Digital Material Science: New Material and Substances” Bauman Moscow State Technical University 2nd Baumanskaya Str., 5 105005 Moscow Russia

Abstract

AbstractOrganotrialkoxysilanes are unique compounds that play an important role in modern science and industry. Their structure determines their varied use both in production and academic research. The development of the synthesis of organotrialkoxysilanes and polymers based on them, taking into account environmental realities, is an important task. In our work, we present an original approach for the preparation of organotriethoxysilanes, starting from azidoalkyltriethoxysilanes and various types of substrates containing a terminal triple bond, by the azide‐alkyne cycloaddition (CuAAC) mechanism without the use of solvents, catalyst ligands, and amines. We also found the self‐catalyzing effect of the triazole fragment resulting from the azide‐alkyne cycloaddition in the reaction of hydrolysis and condensation of alkoxy groups, which made it possible to obtain a series of silsesquioxane products only by adding water, without the use of catalysts. As a result, a new, original scheme for the preparation of organosilicon organotrialkoxysilanes of a monomeric structure with their subsequent transformation into silsesquioxane polymers under “green” conditions is built.

Funder

Russian Science Foundation

Publisher

Wiley

Subject

General Chemistry

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