Atomic-scale Engineering of Magnetic Graphene Nanostructures

Graphene can develop large magnetic moments in custom crafted open-shell nanostructures such as triangulene, a triangular piece of graphene with zigzag edges. Current methods of engineering graphene nano-systems on surfaces succeeded in producing atomically precise open-shell structures, but demonstration of their net spin remains elusive to date. Here, we fabricate triangulene-like graphene systems and demonstrate that they possess a spin $S=1$ ground state. Scanning tunnelling spectroscopy identifies the fingerprint of an underscreened $S=1$ Kondo state on this flakes at low temperatures, signaling the dominant ferromagnetic interactions between two spins. Combined with simulations based on the mean-field Hubbard model, we show that this $S=1$ $\pi$-paramagnetism is robust, and can be manipulated to a weaker $S=1/2$ state by adding additional H-atoms to the radical sites, or by fabricating larger structures. The observation of a net magnetic moment in pure-carbon nanostructures opens promising perspectives for utilizing graphene in quantum spintronics applications.