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 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 work, we study quantum transport properties of superlattice-graphene nanoribbons
(SGNRs) attached to two semi-infinite metallic armchair graphene nanoribbon (AGNR) …

We study the electron transport in metallic carbon nanotubes (CNTs) with realistic defects of
different types. We focus on large CNTs with many defects in the mesoscopic range. In a …

We study the transport properties of defective single-walled armchair carbon nanotubes
(CNTs) on a mesoscopic length scale. Monovacancies and divancancies are positioned …

Aiming at an efficient method to determine the transport properties of a physical system, an
effective and accurate band‐counting algorithm is presented to extract the transmission …

We introduce a new method based on the tight-binding model and mode space (MS)
renormalization approach to the study of quantum transport properties of carbon-based …

We derive an improved version of the recursive Green's function formalism (RGF), which is a
standard tool in the quantum transport theory. We consider the case of disordered quasi one …

We examine quantum transport properties of a graphene system with several different
configurations, which the scatter region and two semi-infinite electrodes are represented by …

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