Reductive Activation of White Phosphorus to [P ₄ ] ^2– , [P ₂ ] ^2–

ABSTRACT

Activation of white phosphorus (P ₄ ) to smaller P _n units by rare‐earth compounds remains a synthetic challenge. Here, we show that the rare‐earth dinitrogen complexes [{(Cp ^ttt ) ₂  M} ₂ (μ‐1,2‐N ₂ )] (M = Y, Gd; Cp ^ttt  = 1,2,4‐tri( tert ‐butyl)cyclopentadienyl), reductively cleave P ₄ to give a homologous series of phosphorus anions of decreasing nuclearity, that is, [{(Cp ^ttt ) ₂  M} ₂ (μ‐P ₄ )] ( 1 _M ), [{(Cp ^ttt ) ₂  M} ₂ (μ‐η ² :η ² ‐P ₂ )] ( 2 _M ), and [{(Cp ^ttt ) ₂  M} ₂ (μ‐P)] ( 3 _M ). Structural, spectroscopic, and computational studies show that 1 _M contains a bicyclobutane‐like [P ₄ ] ^2– ligand, whereas 2 _M features a side‐on coordinated [P═P] ^2– ligand, and 3 _M comprises a monatomic P ^2– ligand formulated as a phosphorus‐centered radical with S  = 1/2. The EPR spectrum of 3 _Y confirms hyperfine coupling to ³¹ P and ⁸⁹ Y, while magnetic measurements on 3 _Gd reveal strong antiferromagnetic exchange between the Gd ³⁺ ions and the radical ligand. Density functional theory supports a three‐center π‐type M–P–M interaction in 3 _M , with the unpaired spin localized primarily on phosphorus and only weak delocalization onto the metal centers. These findings represent progressive fragmentation of P ₄ to diatomic and monatomic phosphorus anions by rare‐earth reagents, thereby extending the chemistry of multiply bonded phosphorus and persistent phosphorus radicals into the rare‐earth series.