Graphene is one of the most promising materials for nanoelectronics owing to its unique
Dirac cone-like dispersion of the electronic state and high mobility of the charge carriers …

Au (001) surfaces exhibit a complex reconstructed structure [Hex− Au (001)] comprising a
hexagonal surface and square bulk lattices, yielding a quasi-one-dimensional corrugated …

Band structure and topology of magneto-spin–orbit graphene is investigated using the
proposed tight-binding model that incorporates both Rashba and sublattice-resolved …

To enhance the spin–orbit interaction in graphene by a proximity effect without
compromising the quasi-free-standing dispersion of the Dirac cones means balancing the …

The proximity-induced effects of the nearly commensurate lattice structure of a graphene
layer AC stacked on Ni (111) and Co (0001) substrates are addressed. To this end, a …

We investigate the production of spin-polarized currents in corrugated graphene
nanoribbons. Such corrugations are modeled as multiple regions with Rashba spin-orbit …

Weak-localization (WL) measurements were performed in a Bi cluster-decorated graphene
sheet. The charge concentration was kept constant, and the amplitude of the conductance …

Two methods to synthesize Bi/Gr composites of Bi nanoparticles on graphene were
developed: a three-step one (method I) and a two-step one (method II). By these methods …

Graphene, as a material with a small intrinsic spin–orbit interaction of approximately 1 µeV,
has a limited application in spintronics. Adsorption of graphene on the surfaces of heavy …

The control of the graphene electronic structure is one of the most important problems in
modern condensed matter physics. The graphene monolayer synthesized on the Re (0001) …