A Crystalline Phosphaalkene Radical Anion

Synthesis and EPR/UV/Vis-NIR spectroelectrochemical investigation of a persistent phosphanyl radical dication

The reaction of the bis(imidazoliumyl)-substituted P(I)  cation [(2-Im(Dipp) )P(4-Im(Dipp) )](+) (10(+) ) (2-Im=imidazolium-2-yl; 4-Im=imidazolium-4-yl; Dipp=2,6-di-isopropylphenyl) with trifluoromethanesulfonic acid (HOTf) or methyl trifluoromethylsulfonate (MeOTf) yields the corresponding protonated [(2-Im(Dipp) )PH(4-Im(Dipp) )](2+) (11(2+) ) and methylated [(2-Im(Dipp) )PMe(4-Im(Dipp) )](2+) (12(2+) ) dications, respectively. EPR/UV/Vis-NIR spectroelectrochemical investigation of the low-coordinated P(I)  cation 10(+) predicted a stable and "bottleable" P-centered radical dication [(2-Im(Dipp) )P(4-Im(Dipp) )](2+.) (13(2+.) ). The reaction of 10(+) with the nitrosyl salt NO[OTf] yields the persistent phosphanyl radical dication 13(2+.) as triflate salt in crystalline form. Quantum chemical investigation revealed an exceptional high spin density at the P atom.

Theoretical Characterisation of Phosphinyl Radicals and Their Magnetic Properties: g Matrix

The g matrices (g tensors) of various phosphinyl radicals (R2 P(.) ) were calculated using the DFT and multireference configuration interaction (MRCI) methods. The g matrices were distinctly dependent on the molecular structure of the radical. To thoroughly examine this dependence, the contributions from individual atoms and excited states were calculated. The former revealed the gain from the phosphorus atom to be preeminent unless PO or PS bonds are present in the radical molecule. The contributions owing to excited states arising from electronic transitions between doubly occupied molecular orbitals and the SOMO were clearly positive, as in the case of semiquinone and niroxide radicals. The transitions from the phosphorus lone pair were of paramount importance. Surprisingly, unlike for semiquinones and nitroxides, a significant negative contribution was observed from excitations from the SOMO to unoccupied molecular orbitals. For radicals with PO bonds, this contribution to the g2 component was dominant.

Two phosphaalkene radical cations with inverse spin density distributions

Two phosphaalkene radical cations have been made by using a weakly coordinating anion, and they exhibit inverse spin density distributions.