Nanostructured superlattices have been the focus of many researchers due to their physical
and manipulatable properties. They aim to find promising materials for new electronic and …

In this paper, we study the structural, electronic, and quantum transport properties in the
smallest fullerene, C 20, and the most famous fullerene, C 60, and their corresponding …

In this paper we study the optical conductivity and density of states (DOS) of doped gapped
graphene beyond the Dirac cone approximation in the presence of electron-phonon (e-ph) …

We report peculiar charge and spin transport properties in S-shaped silicene junctions with
the Kane–Mele tight-binding model. In this work, we investigate the effects of electric and …

In this paper, we study spin transport properties of silicene structures such as ribbons and
superlattices with the Kane–Mele model. We investigate the effects of ferromagnetic and …

In this paper, we investigate the thermal transport in Si nanowires by using nonequilibrium
molecular dynamics simulations (NEMD). We focus on the effects of axial torsion and …

The effect of chemical functionalization on the electronic properties of graphene nanoribbon
superlattices with zigzag and armchair terminations is investigated using the density …

In this paper, the spin-dependent transport and the spin polarization properties for graphene
superlattice with Rashba spin–orbit interaction (RSOI) in the presence of zigzag and …

In this paper, we study electrical properties of AB-stacked bilayer graphene-DNA hybrid
nanostructure connected to two semi-infinite monolayer graphene nanoribbon leads. We …

Using the tight-binding model, electronic quantum transport properties of strained
superlattice-graphene nanoribbons (SGNRs) attached to two semi-infinite metallic leads are …