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A few-layer covalent network of fullerenes.

Elena MeirzadehAustin M EvansMehdi RezaeeMilena MilichConnor J DionneThomas P DarlingtonSi Tong BaoAmymarie K BartholomewTaketo HandaDaniel J RizzoRen A WisconsMahniz RezaAmirali ZangiabadiNatalie Fardian-MelamedAndrew C CrowtherP James SchuckDmitri N BasovXiaoyang ZhuAshutosh GiriPatrick E HopkinsPhilip KimMichael L SteigerwaldJingjing YangColin P NuckollsXavier Roy
Published in: Nature (2023)
The two natural allotropes of carbon, diamond and graphite, are extended networks of sp 3 -hybridized and sp 2 -hybridized atoms, respectively 1 . By mixing different hybridizations and geometries of carbon, one could conceptually construct countless synthetic allotropes. Here we introduce graphullerene, a two-dimensional crystalline polymer of C 60 that bridges the gulf between molecular and extended carbon materials. Its constituent fullerene subunits arrange hexagonally in a covalently interconnected molecular sheet. We report charge-neutral, purely carbon-based macroscopic crystals that are large enough to be mechanically exfoliated to produce molecularly thin flakes with clean interfaces-a critical requirement for the creation of heterostructures and optoelectronic devices 2 . The synthesis entails growing single crystals of layered polymeric (Mg 4 C 60 ) ∞ by chemical vapour transport and subsequently removing the magnesium with dilute acid. We explore the thermal conductivity of this material and find it to be much higher than that of molecular C 60 , which is a consequence of the in-plane covalent bonding. Furthermore, imaging few-layer graphullerene flakes using transmission electron microscopy and near-field nano-photoluminescence spectroscopy reveals the existence of moiré-like superlattices 3 . More broadly, the synthesis of extended carbon structures by polymerization of molecular precursors charts a clear path to the systematic design of materials for the construction of two-dimensional heterostructures with tunable optoelectronic properties.
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