Organophosphorus Compounds, 119 . The Phosphaalkyne Cyclotetramer System — Syntheses, Valence Isomerizations, and Reactions

In contrast to their all‐carbon analogues, phosphaalkyne cyclooligomers only became accessible a few years ago. A milestone in the chemistry of cyclotetramers was the synthesis and structural characterization of the tetraphosphacubane 5 , obtained as a thermolysis product of tert‐butylphosphaacetylene ( 1 ). Since then, the construction of eleven cyclotetramers has been achieved, covering seven different frameworks ( A‐G ). As a consequence of the use of kinetically stabilized phosphaalkynes as starting materials, all known cyclotetramers bear sterically demanding substituents (tert‐butyl, tert‐pentyl, 1‐adamantyl). Cyclotetramerizations are not only achieved by thermolysis of 1 , but also by alternative and selective routes such as transition‐metal‐mediated, Lewis acid‐ and base‐induced processes, as well as by cycloadditions to phosphaalkyne cyclotrimers. Interestingly, these tetramers can be interconverted by various valence isomerizations. The results of thermal and photochemically‐induced rearrangements are in good agreement with MO calculations carried out for the parent compounds. Phosphaalkyne cyclotetramers exhibit a highly interesting reactivity and other peculiar features. One outstanding example is the tetraphosphacubane 5 , which shows unusual structural and spectroscopic properties as a result of its unique bonding arrangement.