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Bandurin, D. A.
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document
Tuneable spin injection in high-quality graphene with one-dimensional contacts
Abstract
Spintronics involves the development of low-dimensional electronic systems that support the creation and control of spin transport, with potential use in quantum-based computation. To advance these efforts structures that support spin transport while enabling high-quality electronic transport are desired, with graphene being an ideal platform to contribute towards this goal. There has been significant progress in improving spin transport characteristics, e.g. by encapsulation and reducing impurities in graphene, but the influence of standard two-dimensional (2D) tunnel contacts, such as pinholes and unintentional doping leading to non-uniformity in the graphene channel, remains difficult to eliminate. Here, we report the observation of efficient spin injection and tuneable spin signal in high-quality and fully-encapsulated graphene, enabled by van der Waals heterostructures with one-dimensional (1D) contacts. This architecture prevents significant doping from the contacts within the graphene channel, allowing the ability to routinely achieve high-quality channels, currently with mobilities up to 130,000 cm2V-1s-1 and spin diffusion lengths approaching 20 micrometer. Despite the direct contact between the ferromagnetic metal and graphene, the nanoscale-wide 1D contacts offer a sizeable contact resistance, allowing spin injection both at room and at low temperature, with the latter exhibiting spin injection efficiency comparable with standard 2D tunnel contacts. Furthermore, owing to gate tuneability of the 1D contacts' resistance at low temperature, the observed spin signals can be enhanced by as much as an order of magnitude by p-doping of the graphene channel, adding new functionality to the device performance.