Researchers at The University of Manchester may have cleared a significant hurdle on the path to quantum computing, demonstrating step-change improvements in the spin transport characteristics of nanoscale graphene-based electronic devices.
The team - comprising researchers from the National Graphene Institute (NGI) led by Dr Ivan Vera Marun, alongside collaborators from Japan and including students internationally funded by Ecuador and Mexico - used monolayer graphene encapsulated by another 2D material (hexagonal boron nitride) in a so-called van der Waals heterostructure with one-dimensional contacts (main picture, above). This architecture was observed to deliver an extremely high-quality graphene channel, reducing the interference or electronic 'doping' by traditional 2D tunnel contacts.
'Spintronic' devices, as they are known, may offer higher energy efficiency and lower dissipation compared to conventional electronics, which rely on charge currents. In principle, phones and tablets operating with spin-based transistors and memories could be greatly improved in speed and storage capacity, exceeding Moore's Law.
As published in Nano Letters, the Manchester team measured electron mobility up to 130,000 cm2/Vs at low temperatures (20K or -253 oC). For purposes of comparison, the only previously published efforts to fabricate a device with 1D contacts achieved mobility below 30,000 cm2/Vs, and the 130 k figure measured at the NGI is higher than recorded for any other previous graphene channel where spin transport was demonstrated.
The researchers also recorded spin diffusion lengths approaching 20 μm. Where longer is better, most typical conducting materials (metals and semiconductors) have spin diffusion lengths <1 μm. The value of spin diffusion length observed here is comparable to the best graphene spintronic devices demonstrated to date.
Lead author of the study Victor Guarochico said: "Our work is a contribution to the field of graphene spintronics. We have achieved the largest carrier mobility yet regarding spintronic devices based on graphene. Moreover, the spin information is conserved over distances comparable with the best reported in the literature. These aspects open up the possibility to explore logic architectures using lateral spintronic elements where long-distance spin transport is needed."
Co-author Chris Anderson added: "This research work has provided exciting evidence for a significant and novel approach to controlling spin transport in graphene channels, thereby paving the way towards devices possessing comparable features to advanced contemporary charge-based devices. Building on this work, bilayer graphene devices boasting 1D contacts are now being characterised, where the presence of an electrostatically tuneable bandgap enables an additional dimension to spin transport control."
Discover more about our capabilities in graphene and 2D material research at the National Graphene Institute website.
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