Radical anion functionalization of two-dimensional materials as a means of engineering simultaneously high electronic and ionic conductivity solids

A radical anion based functionalization of the basal plane of two-dimensional (2D) materials is proposed in the present study. Simple charge neutral radical functionalizations typically detach from the basal planes upon reduction. For example, epoxy oxygens irreversibly detach from graphene when reduced by an alkali metal. The radical anion functionalization of 2D materials results in a stable reduced state that can reversibly be oxidized and has high ionic conductivity due to the great mobility of the cations between the negatively charged functional groups on the surface. Depending on the oxidation state of these systems, a high concentration of hole states can also be realized allowing for good electronic conductivity. These properties can further allow for improved energy storage devices via transition metal free cathode active species, solid electrolytes, electroconductive additives, separators, coatings for metal anodes and heat conductors through a single material. One possible realization of the above principles is the 2D salt An(BN)2OBX3, where A is an alkali atom (Li, Na, etc; 0=