From Humorous Post to Detailed Quantum-Chemical Study: Isocyanate Synthesis Revisited

Isocyanates play an essential role in modern manufacturing processes, especially in polyurethane production. There are numerous synthesis strategies for isocyanates both in industrial and laboratory conditions, which do not prevent searching for alternative highly efficient synthetic protocols. Here...

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Bibliographic Details
Published in:ChemRxiv 2024-02
Main Authors: Beletsan, Oleg B., Gordiy, Igor, Lunkov, Sergey S., Kalinin, Mikhail A., Alkhimova, Larisa E., Nosach, Egor A., Ilin, Egor A., Bespalov, Alexandr V., Dallakyan, Olgert L., Chamkin, Aleksandr A., Prolomov, Ilya V., Zaripov, Radion A., Pershin, Andrey A., Protsenko, Bogdan O., Rusalev, Yury V., Oganov, Ruslan A., Kovaleva, Diana K., Mironov, Vladimir A., Dotsenko, Victor V., Genaev, Alexandr M., Sharapa, Dmitry I., Tikhonov, Denis
Format: Article
Language:English
Subjects:
Catalysis
Catalysts
Chemical synthesis
Chemistry
Computational Chemistry and Modeling
Homogeneous Catalysis
Isocyanates
Organic Chemistry
Polyurethane resins
Quantum chemistry
Reaction kinetics
Selenium dioxide
Social networks
Sulfur dioxide
Sulfur trioxide
Theoretical and Computational Chemistry
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Summary:Isocyanates play an essential role in modern manufacturing processes, especially in polyurethane production. There are numerous synthesis strategies for isocyanates both in industrial and laboratory conditions, which do not prevent searching for alternative highly efficient synthetic protocols. Here, we report a detailed theoretical investigation of the mechanism of sulfur dioxide-catalyzed rearrangement of the phenylnitrile oxide into phenyl isocyanate, which was first reported in 1977. The DLPNO-CCSD(T) method and up-to-date DFT protocols were used to perform a highly accurate quantum-chemical study of the rearrangement mechanism. An overview of various organic and inorganic catalysts has revealed other potential catalysts, such as sulfur trioxide and selenium dioxide. Furthermore, the present study elucidated how substituents in phenylnitrile oxide influence reaction kinetics. This study was performed by a self-organized collaboration of scientists initiated by a humorous post on the VK social network.
ISSN:2573-2293
DOI:10.26434/chemrxiv-2023-02n4r-v2