Corrigendum to: Barium as Honorary Transition Metal in Action: Experimental and Theoretical Study of Ba(CO) ⁺ and Ba(CO) ⁻ (Angewandte Chemie International Edition, (2018), 57, 15, (3974-3980), 10.1002/anie.201713002)

In this Communication, for the calculations of the anion [Ba(CO)]⁻ neutral Ba and the carbonyl anion CO⁻ were considered as interacting fragments. The choice was made on the basis of the experimental literature values for the electron affinities (EAs) of Ba (0.108 eV, average value of ²P_1/2 and ²P_3/2) and CO (1.37 eV). The authors now learned that the experimental value for the EA of CO is incorrect. High-level quantum chemical calculations suggest that CO has a negative EA, i.e. the attached electron in CO⁻ is unbound and the anion is a resonance species that may only be observed as metastable resonating species via sophisticated spectroscopy. This means that the bonding analysis of the anion [Ba(CO)]⁻ and the calculation of the bond dissociation energy (BDE) must be carried out using the fragments Ba⁻ and neutral CO. The results of the relevant calculations are reported here. The calculated BDE for the reaction [Ba(CO)]⁻ → Ba⁻ + CO at DLPNO-CCSD(T)/def2-QZVPPD using the CCSD/def2-TZVPP optimized geometries is D_e = 15.6 kcal mol⁻¹, significantly lower than the previous value of 56.1 kcal mol⁻¹ that was obtained with respect to Ba and CO⁻ at the same level of theory. The numerical results of the EDA-NOCV analysis of [Ba(CO)]⁻ using Ba⁻ in the ²D state and CO as fragments are shown in Table, together with the previous data using Ba (¹S) and CO⁻(²Π) as fragments. The intrinsic interaction energy with the former fragments ΔE_int = −25.6 kcal mol⁻¹ is also significantly lower than the previous value ΔE_int = −71.4 kcal mol⁻¹. EDA-NOCV results of BaCO⁻ at the M06-2X/TZ2P+ level of theory with different fragments using the CASSCF(5,6)/def2-TZVPD optimized structure of BaCO⁻. Energy values are given in kcal mol⁻¹. (Table presented.) [a] The values in parentheses give the percentage contribution to the total attractive interactions ΔE_elstat + ΔE_orb. [b] The values in parentheses give the percentage contribution to the total orbital interactions ΔE_orb. The partitioning of the orbital term into the most important pairwise interactions gives in both cases two dominant interactions. The largest contribution ΔE_orb(1) comes from the donation of the unpaired π electron at Ba⁻ to the LUMO of CO (Figure a). This was also found in the original work as the strongest orbital interaction in the cation Ba(CO)⁺, where the electronic reference state of Ba⁺ cation is the excited ²D state that makes it to become a donor Ba⁺→CO. The deformation density, which is associated with the second strongest orbital interaction shows that ΔE_orb(2) comprises two alterations of the electronic charges (Figure b). There is a polarization at barium, where the occupied 6 s AO of Barium mixes with vacant p(σ) and d(σ) orbitals and a concomitant donation from the HOMO of CO into the σ hybrid AO at Ba. Figure (Figure presented.) Shape of the most important interacting MOs of fragments and plot of the associated deformation densities Δρ of the most important pairwise orbital interactions ΔE_orb(1) and ΔE_orb(2) BaCO⁻. The direction of the charge flow is red→blue. Thus, the most important finding in the original work remains the same: The chemical bonds of barium in the carbonyl complexes [Ba(CO)]⁺ and [Ba(CO)]⁻ use mainly the 5 d AOs as valence orbitals. The use of the (n−1) d functions as genuine valence orbitals not only by barium but also by the lighter alkaline earth atoms calcium and strontium has in the meantime been supported by the experimental observation of the octacarbonyls E(CO)₈ (E = Ca, Sr, Ba), which mimic transition metal complexes. The authors are grateful to Prof. Peter Schwerdtfeger, who pointed out the error of choosing the wrong interacting fragments for [Ba(CO)]⁻.