Analysis of the electronic delocalization in some isoelectronic analogues of B₁₂doped with beryllium and/or carbon

In the current work, a new family of isoelectronic analogues to B₁₂is reported. The construction of this family was performed through the isoelectronic substitution principle to generate species such as B₁₁C⁺, B₁₁Be⁻, B₁₀BeC, B₁₀C₂²⁺, B₁₀Be₂²⁻B₉Be₂C⁻, and B₉BeC₂⁺. The search for the global minimum was realized by utilizing genetic algorithms, while the induced magnetic field, electronic localization function, magnetic current densities, and multicenter aromaticity criteria were calculated to understand their electronic delocalization. Our results show that, in general, C atoms avoid hypercoordination, whereas we have found species with Be atoms located in hypercoordinated positions that are relatively stable. Our analysis of aromaticity indicates that B₁₂has double σ and π disk aromaticity. Mono, double or triple substitution of B by C⁺or Be⁻reduces somewhat the aromaticity of the clusters, but less in the case of Be⁻substitution.