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Abstract
Two lithium phospha-enolates [RP=C(SiiPr3)OLi]2 were prepared by reduction of triisopropyl silyl phosphaethynolate, iPr3SiPCO, with aryl lithium reagents LiR (R = Mes: 1,3,5-trimethyl phenyl; or Mes*: 1,3,5,-tri-tert-butyl phenyl). Monomer/dimer aggregation of the enolates can be modulated by addition of 12-crown-4. Substitution of lithium for a heavier alkali metal was achieved through initial formation of a silyl enol ether, followed by reaction with KOtBu to form the corresponding potassium phospha-enolate [MesP=C(SiiPr3)OK]2. On addition of water, the enolates are protonated to afford RP=C(SiiPr3)(OH). For the sterically less demanding system (R = Mes), this phospha-enol rapidly tautomerises to the corresponding acyl phosphine MesP(H)C(SiiPr3)(O), which on heating extrudes CO. In contrast, bulkier phospha-enol (R = Mes*) is stable to rearrangement at room temperature and thermally decomposes to RH and iPr3SiPCO.
Supplementary materials
Title
Supplementary Information
Description
Details of novel compound synthesis and characterisation, and density functional theory calculations.
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