Ambient-Pressure Superconductivity from Boron Icosahedral Superatoms

Abstract

We identify a new family of boron-rich compounds consisting of interconnected B12 icosahedra, and electropositive guest atoms (X) in interstitial sites. These structures were found through first-principles crystal structure prediction at 50 GPa, where they could form, and are dynamically stable down to ambient pressure, so they could be formed under pressure, and brought back. When X is a mono- or trivalent element the structures are metallic and superconducting. Predicted critical temperatures reach up to 42 K for CsB12, rivaling MgB2, the highest-Tc ambient-pressure conventional superconductor. We interpret the XB12 phase as a superatomic crystal: the B12 units retain the icosahedral shape that they also exhibit in isolation, while forming an extended crystalline network. When X is a mono- or tri-valent atom, the system is metallic, and the B--B covalent bonding promotes strong electron-phonon coupling. Unlike MgB2, where superconductivity is driven by a narrow subset of phonon modes, the XB12 compounds exhibit broad, mode- and momentum-distributed coupling through both intra- and inter-superatomic vibrations. Our results highlight the XB12 family as a promising platform for superconductivity and demonstrate the potential of superatoms as functional building blocks in solid-state materials design.