Radical Reactivity of Frustrated Lewis Pairs with Diaryl Esters

Yashar Soltani,Ayan Dasgupta,Theodore A Gazis,Darren M.C Ould,Emma Richards,Ben Slater,Katarina Stefkova,Vladimir Y Vladimirov,Lewis C Wilkins,Darren Willcox,Rebecca L Melen

doi:10.1016/j.xcrp.2020.100016

Yashar Soltani, Ayan Dasgupta + Show 9 more

Open Access

https://doi.org/10.1016/j.xcrp.2020.100016

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Abstract

Advances in the chemistry of metal-free systems known as frustrated Lewis pairs (FLPs) has exposed new reactivity of the p-block elements, particularly in small-molecule activation and catalysis. Typically, the mode of activation by FLPs has been predicated on a heterolytic two-electron process, although recently, select FLPs have been shown to participate in single-electron processes. Here, we report the reaction of diaryl substituted esters with FLPs. This results in divergent pathways, one whereby the diaryl moiety is stabilized by the Lewis basic phosphine, and the alternative pathway, wherein a single-electron transfer process occurs, generating the [Mes3P]+⋅/[C(H)Ar2]⋅ radical ion pair. The latter species undergoes a homocoupling reaction to yield tetraphenylethane derivatives. In the presence of olefins, this reactivity can be harnessed through an sp2-sp3 C–C heterocoupling reaction to generate α,β-substituted olefins. Notably, this work showcases an FLP approach to metal-free radical C–H bond activation with subsequent C–C bond formation, which also displays complementary reactivity to other approaches.

Highlights

A revolutionary paradigm shift occurred in 2006 with the first report of a non-metal system 4-(Mes2P)C6F4(B(C6F5)2), which could reversibly activate dihydrogen.[1]
Advances in the chemistry of metal-free systems known as frustrated Lewis pairs (FLPs) has exposed new reactivity of the p-block elements, in smallmolecule activation and catalysis
The mode of activation by FLPs has been predicated on a heterolytic two-electron process, recently, select FLPs have been shown to participate in single-electron processes

Summary

Introduction

A revolutionary paradigm shift occurred in 2006 with the first report of a non-metal system 4-(Mes2P)C6F4(B(C6F5)2), which could reversibly activate dihydrogen.[1]. We report the reaction of diaryl substituted esters with FLPs. This results in divergent pathways, one whereby the diaryl moiety is stabilized by the Lewis basic phosphine, and the alternative pathway, wherein a single-electron transfer process occurs, generating the [Mes3P]+,/[C(H)Ar2], radical ion pair.

Results

Conclusion