Why does B12H12-icosahedron need two electrons to be stable: A first-principles electron-correlated investigation of B12Hn (n=6,12) clusters

Abstract

In this work, we present large-scale electron-correlated computations on various conformers of B12H12 and B12H6 clusters, to understand the reasons behind the high stability of di-anion icosahedron (Ih) and cage-like B12H6 geometries. Although the B12-icosahedron is the basic building block in some structures of bulk boron, it is unstable in its free form. Furthermore, its H-passivated entity, i.e., B12H12 icosahedron is also unstable in free form. However, dianion B12H12 has been predicted to be stable as a perfect icosahedron in the free-standing form. In order to capture the correct picture for the stability of B12H12-2 and B12H6 clusters, we optimized these structures by employing the coupled-cluster singles-doubles (CCSD) approach and cc-pVDZ basis set. We also performed vibrational frequency analysis of the isomers of these clusters, using the same level of theory to ensure the stability of the structures. For all the stable geometries obtained from the vibrational frequency analysis, we additionally computed their optical absorption spectra using the time-dependent density functional theory (TDDFT) approach, at the the B3LYP/6-31G* level of theory. Our calculated absorption spectra could be probed in future experiments on these clusters.