Abstract
Superatomic crystals comprising ligand-capped, metal chalcogenide clusters and fullerenes are modular materials that exhibit enhanced electronic, magnetic, and thermal conductivity properties. We find that neutral, M(4)S(4) (M = Fe, Co) clusters stabilized with N-heterocyclic carbenes (NHCs) can transfer charge to C(60) fullerene to form binary superatomic crystals. Notably, these compounds are soluble in various organic solvents, allowing their properties to be investigated in solution, unlike traditional fullerene-based superatomic crystals. The ion pairs can be further assembled into organometallic polymers using Janus-bis-(NHCs) to cross-link the oxidized M(4)S(4) units. We show that the superatomic polymers are more conductive than both the precursor superatomic crystals and the polymers containing only neutral M(4)S(4) clusters. Similar conductivity values can be obtained when neutral M(4)S(4)-NHC polymers are doped with solutions of C(60) fullerene. These findings demonstrate that next generation superatomic materials can be prepared via the combination of charge transfer and polymerization with appropriate cross-linking agents.