Abstract
Lewis acids increase the catalytic activity of classical heterogeneous catalysts and molecular d0 tungsten oxo alkylidenes in a variety of olefin metathesis processes. The formation of labile adducts between the metal complex and the Lewis acid has been observed experimentally and suggested to be involved in the catalyst activity increase. In this contribution, DFT (M06) calculations have been performed to determine the role of Lewis acids on catalyst activity, Z-/E- selectivity and stability by comparing three W(E)(CHR)(2,5-dimethylpyrrolide)(O-2,6-dimesithylphenoxide) (E = oxo, imido or oxo-Lewis acid adduct) alkylidenes. Results show that the formation of the alkylidene—Lewis acid adducts influences the reactivity of tungsten oxo alkylidenes due to both steric and electronic effects. The addition of the Lewis acid on the E group increases its bulkiness and this decreases catalyst Z-selectivity. Moreover, the interaction between the oxo ligand and the Lewis acid decreases the donating ability of the former toward the metal. This is important when the oxo group has either a ligand in trans or in the same plane that is competing for the same metal d orbitals. Therefore, the weakening of oxo donating ability facilitates the cycloaddition and cycloreversion steps and it stabilizes the productive trigonal bipyramid metallacyclobutane isomer. The two factors increase the catalytic activity of the complex. The electron donating tuneability by the coordination of the Lewis acid also applies to catalyst deactivation and particularly the key β-hydride elimination step. In this process, the transition states show a ligand in pseudo trans to the oxo. Therefore, the presence of the Lewis acid decreases the Gibbs energy barrier significantly. Overall, the optimization of the E group donating ability in each step of the reaction makes tungsten oxo alkylidenes more reactive and this applies both for the catalytic activity and catalyst deactivation.
Highlights
Olefin metathesis is a key reaction in organic synthesis that implies the exchange of alkylidene substituents between alkenes
We compare the results obtained for 13-I and 9W-I ethylidene complexes as well as the oxo complex interacting with two Lewis acids B(C6F5)3 (13·B(C6F5)3-I) and BF3 (13·BF3-I), see Scheme 2
DFT (M06) calculations have been performed to rationalize the effect of Lewis acids on the catalytic activity for olefin metathesis, Z-/E- selectivity and catalyst stability of tungsten oxo alkylidene complexes
Summary
Olefin metathesis is a key reaction in organic synthesis that implies the exchange of alkylidene substituents between alkenes. It has been applied to the synthesis of a large variety of molecules including raw materials, polymers, and drugs [1,2,3,4,5,6,7,8]. The reaction only takes place in presence of a catalyst. Silica and alumina supported molybdenum and tungsten oxides are within the first catalyst precursors and they have been applied in industrial applications util today [9]. The active species operating in these systems has not been characterized in detail, but they are thought to be metal oxo alkylidenes.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
