Self-assembly and photoinduced fabrication of conductive nanographene wires on boron nitride.
Xiaoxi ZhangFabian GärischZongping ChenYunbin HuZishu WangYan WangLiming XieJianing ChenJuan LiJohannes V BarthAkimitsu NaritaEmil J W List-KratochvilKlaus MüllenCarlos-Andres PalmaPublished in: Nature communications (2022)
Manufacturing molecule-based functional elements directly at device interfaces is a frontier in bottom-up materials engineering. A longstanding challenge in the field is the covalent stabilization of pre-assembled molecular architectures to afford nanodevice components. Here, we employ the controlled supramolecular self-assembly of anthracene derivatives on a hexagonal boron nitride sheet, to generate nanographene wires through photo-crosslinking and thermal annealing. Specifically, we demonstrate µm-long nanowires with an average width of 200 nm, electrical conductivities of 10 6 S m -1 and breakdown current densities of 10 11 A m -2 . Joint experiments and simulations reveal that hierarchical self-assembly promotes their formation and functional properties. Our approach demonstrates the feasibility of combined bottom-up supramolecular templating and top-down manufacturing protocols for graphene nanomaterials and interconnects, towards integrated carbon nanodevices.