Graphene

Researchers from Europe developed heterostructures built from graphene and topological insulators and have shown the strong tunability and suppression of the spin signal and spin lifetime in these structures.

Associate Professor Saroj Prasad Dash from Chalmers University of Technology explains that the advantage of using heterostructures built from two Dirac materials is tha graphene in proximity with topological insulators still supports spin transport, and concurrently acquires a strong spin–orbit coupling.

Researchers from Russia, Germany and Spain managed to modify graphene to make the material both magnetic and with spin-orbit interaction, for the first time. This could make graphene suitable for quantum computers.

To achieve these new properties, the researchers combined graphene with gold and cobalt. The spin-orbit interaction, unlike in gold, is extremely small in graphene. The interaction between graphene and gold increases the spin-orbit interaction in graphene, while interaction between graphene and cobalt induced magnetism.

Zeila Zanolli,a principal investigator at RWTH Aachen University and the European Theoretical Spectroscopy Facility (ETSF) gave a lecture at the MaX Conference on the Materials Design Ecosystem at the Exascale last month, titled "Spintronics at the interface".

Zeila specifically discusses the interface between Graphene and BaMnO₃ materials.

Researchers from Spain's ICN2 institute have performed numerical simulations for spin relaxation in graphene/TMDC heterostructures, and found that these structure feature a spin lifetime anisotropy that is orders of magnitude larger than anything observed in 2D materials - and in fact these results point to a qualitatively new regime of spin relaxation.

Spin relaxation lifetime means that time it takes for the spin of electrons in a spin current to lose their spin (return to the natural random disordered state). A long lifetime is very important for spintronics devices. This new study reveals that the rate at which spins relax in graphene/TMDC systems depends strongly on whether they are pointing in or out of the graphene plane, with out-of-plane spins lasting tens or hundreds of times longer than in-plane spins.