Homoatomic cations: From [P5]+ to [P9]+ | Science Advances

Recent synthetic approaches to a series of [P ₉ ] X salts ( X = [F{Al(OR ^F ) ₃ } ₂ ], [Al(OR ^F ) ₄ ], and (R ^F = C(CF ₃ ) ₃ ); Ga ₂ Cl ₇ ) overcome limitations in classical synthesis methods that proved unsuitable for phosphorus cations. These salts contain the homopolyatomic cation [P ₉ ] ⁺ via (I) oxidation of P ₄ with NO[F{Al(OR ^F ) ₃ } ₂ ], (II) the arene-stabilized Co(I) sandwich complex [Co(arene) ₂ ][Al(OR ^F ) ₄ ] [arene = ortho -difluorobenzene ( o -DFB) and fluorobenzene (FB)], or (III) the reduction of [P ₅ Cl ₂ ][Ga ₂ Cl ₇ ] with Ga[Ga ₂ Cl ₇ ] as Ga(I) source in the presence of P ₄ . Quantum chemical CCSD(T) calculations suggest that [P ₉ ] ⁺ formation from [Co(arene) ₂ ] ⁺ occurs via the nido-type cluster [( o -DFB)CoP ₄ ] ⁺ , which resembles the isoelectronic, elusive [P ₅ ] ⁺ . Apparently, the nido-cation [P ₅ ] ⁺ forms intermediately in all reactions, particularly during the Ga(I)-induced reduction of [P ₅ Cl ₂ ] ⁺ and the subsequent pick up of P ₄ to yield the final salt [P ₉ ][Ga ₂ Cl ₇ ]. The solid-state structure of [P ₉ ][Ga ₂ Cl ₇ ] reveals the anticipated D _2d -symmetric Zintl-type cage for the [P ₉ ] ⁺ cation. Our approaches show great potential to bring other [P _n ] ⁺ cations from the gas to the condensed phase.