This article reviews the theoretical and experimental work related to the electronic properties
of bilayer graphene systems. Three types of bilayer stackings are discussed: the AA, AB, and …

We review the electronic properties of bilayer graphene, beginning with a description of the
tight-binding model of bilayer graphene and the derivation of the effective Hamiltonian …

We describe how to apply the recursive Green's function method to the computation of
electronic transport properties of graphene sheets and nanoribbons in the linear response …

Advances in large-area graphene synthesis via chemical vapour deposition on metals like
copper were instrumental in the demonstration of graphene-based novel, wafer-scale …

Graphene is the strongest material ever studied and can be an efficient substitute for silicon.
This six-volume handbook focuses on fabrication methods, nanostructure and atomic …

When graphene is placed on a monolayer of semiconducting transition metal
dichalcogenide (TMD) its band structure develops rich spin textures due to proximity spin …

In physics, it is sometimes desirable to compute the so-called density of states (DOS), also
known as the spectral density, of a real symmetric matrix A. The spectral density can be …

In recent years, predictive computational modeling has become a cornerstone for the study
of fundamental electronic, optical, and thermal properties in complex forms of condensed …

We use an exact solution of the relaxation-time Boltzmann equation in a uniform ac electric
field to describe the nonlinear optical response of graphene in the terahertz (THz) range …

We show that by enclosing graphene in an optical cavity, giant Faraday rotations in the
infrared regime are generated and measurable Faraday rotation angles in the visible range …