Endohedral and exohedral metalloborospherenes: M@B40 (M=Ca, Sr) and M&B40 (M=Be, Mg).

Abstract

The recent discovery of the all-boron fullerenes or borospherenes, D(2d) B40(-/0), paves the way for borospherene chemistry. Here we report a density functional theory study on the viability of metalloborospherenes: endohedral M@B40 (M=Ca, Sr) and exohedral M&B40 (M=Be, Mg). Extensive global structural searches indicate that Ca@B40 (1, C(2v), (1)A1) and Sr@B40 (3, D(2d), (1)A1) possess almost perfect endohedral borospherene structures with a metal atom at the center, while Be&B40 (5, C(s), (1)A') and Mg&B40 (7, C(s), (1)A') favor exohedral borospherene geometries with a η(7)-M atom face-capping a heptagon on the waist. Metalloborospherenes provide indirect evidence for the robustness of the borospherene structural motif. The metalloborospherenes are characterized as charge-transfer complexes (M(2+)B40(2-)), where an alkaline earth metal atom donates two electrons to the B40 cage. The high stability of endohedral Ca@B40 (1) and Sr@B40 (3) is due to the match in size between the host cage and the dopant. Bonding analyses indicate that all 122 valence electrons in the systems are delocalized as σ or π bonds, being distributed evenly on the cage surface, akin to the D(2d) B40 borospherene.