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Gate-Tunable Magnetism and Giant Magnetoresistance in Suspended Rhombohedral-Stacked Few-Layer Graphene

Yong-Jin Lee, Shi Che, Jairo Velasco, Xueshi Gao, Yanmeng Shi, David Tran, Jacopo Baima, Francesco Mauri, Matteo Calandra, Marc Bockrath, Chun Ning Lau

2022Nano Letters34 citationsDOI

Abstract

Conventionally, magnetism arises from the strong exchange interaction among the magnetic moments of d- or f-shell electrons. It can also emerge in perfect lattices from nonmagnetic elements, such as that exemplified by the Stoner criterion. Here we report tunable magnetism in suspended rhombohedral-stacked few-layer graphene (r-FLG) devices with flat bands. At small doping levels (n ∼ 1011 cm–2), we observe prominent conductance hysteresis and giant magnetoconductance that exceeds 1000% as a function of magnetic fields. Both phenomena are tunable by density and temperature and disappear at n > 1012 cm–2 or T > 5 K. These results are confirmed by first-principles calculations, which indicate the formation of a half-metallic state in doped r-FLG, in which the magnetization is tunable by electric field. Our combined experimental and theoretical work demonstrate that magnetism and spin polarization, arising from the strong electronic interactions in flat bands, emerge in a system composed entirely of carbon atoms.

Topics & Concepts

MagnetismCondensed matter physicsGrapheneMaterials scienceMagnetizationMagnetoresistanceDopingMagnetic momentMagnetic fieldNanotechnologyPhysicsQuantum mechanicsGraphene research and applications2D Materials and ApplicationsTopological Materials and Phenomena