Air-stable 18-electron adducts of Schrock catalysts with tuned stability constants for spontaneous release of the active species

Henrik Gulyás; Shigetaka Hayano; Ádám Madarász; Imre Pápai; Márk Szabó; Ágota Bucsai; Eddy Martin; Jordi Benet-Buchholz

doi:10.1038/s42004-021-00503-4

Air-stable 18-electron adducts of Schrock catalysts with tuned stability constants for spontaneous release of the active species

Commun Chem. 2021 May 19;4(1):71. doi: 10.1038/s42004-021-00503-4.

Authors

Henrik Gulyás¹, Shigetaka Hayano², Ádám Madarász³, Imre Pápai⁴, Márk Szabó⁵, Ágota Bucsai⁵, Eddy Martin^{6

7}, Jordi Benet-Buchholz⁶

Affiliations

¹ XiMo Hungary Ltd, Berlini Park, Budapest, Hungary. henrik.gulyas@ximo-inc.com.
² Zeon Corporation, Tokyo, Japan.
³ Research Center for Natural Sciences, Institute of Organic Chemistry, Budapest, Hungary.
⁴ Research Center for Natural Sciences, Institute of Organic Chemistry, Budapest, Hungary. papai.imre@ttk.hu.
⁵ XiMo Hungary Ltd, Berlini Park, Budapest, Hungary.
⁶ Institute of Chemical Research of Catalonia (ICIQ), Barcelona Institute of Science and Technology (BIST), Tarragona, Spain.
⁷ Bruker France SAS, Wissembourg, France.

Abstract

Schrock alkylidenes are highly versatile, very active olefin metathesis catalysts, but their pronounced sensitivity to air still hinders their applications. Converting them into more robust but inactive 18-electron adducts was suggested previously to facilitate their handling. Generating the active species from the inactive adducts, however, required a high-temperature Lewis acid treatment and resulted in an insoluble by-product, limiting the practicality of the methodology. Herein, we introduce an approach to circumvent the inconvenient, costly, and environmentally taxing activation process. We show that 18-electron adducts of W- and Mo-based Schrock catalysts with finite stability constants (typically K = 200-15,000 M^-1) can readily be prepared and isolated in excellent yields. The adducts display enhanced air-stability in the solid state, and in solution they dissociate spontaneously, hence liberating the active alkylidenes without chemical assistance.