KID Procedure Applied on the [(PY5Me2)MoO]+ Complex

The KID (Koopmans in DFT) protocol usually applies in organic molecules of the closed-shell type. We used the KID procedure on an open-shell Mo-based system for the first time to choose the most suitable density functional to compute global and local reactivity descriptors obtained from the conceptual density-functional theory (DFT). From a set of 18 density functionals, spread from the second until the fourth rung of Jacob's ladder: BLYP, BP86, B97-D, MN12-L, MN15-L, M06-L, M11-L, CAM-B3LYP, PBE0, B3LYP, N12-SX, M06-2X, MN15, MN12-SX, ωB97X-D, M11, LC-ωHPBE, and APFD, we concluded that CAM-B3LYP provides the best outcome, and in the second place, M06-2X. Because the vertical first ionization potential and vertical first electron affinity in the ground state (gs) are defined as follows I = E gs ( N - 1) - E gs ( N ) and A = E gs ( N ) - E gs ( N + 1), where E gs ( N - 1), E gs ( N ), and E gs ( N + 1) correspond to energies of the system bearing N , N + 1, and N - 1 electrons, along with Koopmans' theorem (KT) given by I ≈ -ε HOMO (ε HOMO , highest occupied molecular orbital energy) and A ≈ -ε LUMO (ε LUMO , lowest unoccupied molecular orbital energy), the deviation from the KT was performed by the use of the index, such that J I = | E gs ( N - 1) - E gs ( N ) + ε HOMO | and J A = | E gs ( N ) - E gs ( N + 1) + ε LUMO |, which are absolute deviations from the perspective of I and A , respectively. Furthermore, the ε SOMO (SOMO: singly-occupied molecular orbital energy) leads us to another index given by |ΔSL| = |ε SOMO - ε LUMO |. Therefore, J HL and |ΔSL| are indexes defined to evaluate the quality of the KT when employed within the context of quantum chemical calculations based on DFT and not the Hartree-Fock theory. We propose the index that could be more suitable to choose the most proper density functional because the J HL and |ΔSL| are independent indexes.