Dative versus electron-sharing bonding in N-imides and phosphane imides R3ENX and relative energies of the R2EN(X)R isomers (E = N, P; R = H, Cl, Me, Ph; X = H, F, Cl).

Quantum chemical calculations using density functional theory BP86 and M06-2X functionals in conjunction with def2-TZVPP basis sets have been carried out on the title molecules. The calculation results reveal that the N-imides R3NNX are always clearly higher in energy than the imine isomers R2NN(X)R. In the case of phosphane imides R3PNX and the isomers R2PN(X)R, the substituent R plays a critical role in determining their relative stabilities. When R is hydrogen or phenyl group, R3PNX are always higher in energy than R2PN(X)R but the former are more stable than the latter when R = Cl. Interestingly, the Me3PNX and Me2PN(X)Me are quite close in energy. The energy decomposition analysis suggests that the P–N bond in the phosphane imides R3PNX (R = H, Cl, Me, Ph; X = H, F, Cl) should be described in terms of an electron-sharing single bond between two charged fragments R3P+-NX− that is supported by (R3P)+←(NX)− π-backdonation. The π-bond contributes 14–21% of the total orbital interactions while the σ-bond provides 60–68% of ΔEorb. [ABSTRACT FROM AUTHOR]