Add to ORKGIn this work, we investigate in parallel physical and mathematical aspects inherent to the problem of confinement of massless Dirac fermions in graphene nanostructures. In a low energy approach, we propose models to describe confining systems in graphene and study how the choice of boundary conditions of the problem - or, equivalently, of domains of the Dirac operator - affects the physical properties of such systems. In this scenario, we concentrate essentially on the study of the physical behavior of graphene nanorings and nanoribbons in response to aspects such as topology, edge and interface geometry and interactions with external fields. At the same time, a rigorous investigation concerning formal aspects of the problem and th...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
In this work, we investigate in parallel physical and mathematical aspects inherent to the problem ...
In 2004, N. Novoselov and A. Geim (Nobel 2010) have isolated a single layer of graphene on a substra...
In the limit of low energy, graphene can be described by a theory of free massless Fermions. In thi...
In the past few years graphene has been shown to be an interesting object of investigation to scient...
We study a family of local boundary conditions for the Dirac problem corresponding to the continuum ...
In this work, we investigate the electronic properties of confined systems, subject to mechanical pe...
We study the energy of quasi-particles in graphene within the Hartree-Fock approximation. The quasi-...
ABSTRACT: The unique ultrarelativistic, massless, nature of electron states in two-dimensional exten...
We study the effects of strain on the electronic properties and persistent current characteristics o...
Dirac-like Hamiltonians, linear in momentum k, describe the low-energy physics of a large set of nov...
In this work, we study the graphene and its physical properties associated with the theory of the t...
The surfaces physics has attracted the attention of many researchers due to the discovery of materia...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
In this work, we investigate in parallel physical and mathematical aspects inherent to the problem ...
In 2004, N. Novoselov and A. Geim (Nobel 2010) have isolated a single layer of graphene on a substra...
In the limit of low energy, graphene can be described by a theory of free massless Fermions. In thi...
In the past few years graphene has been shown to be an interesting object of investigation to scient...
We study a family of local boundary conditions for the Dirac problem corresponding to the continuum ...
In this work, we investigate the electronic properties of confined systems, subject to mechanical pe...
We study the energy of quasi-particles in graphene within the Hartree-Fock approximation. The quasi-...
ABSTRACT: The unique ultrarelativistic, massless, nature of electron states in two-dimensional exten...
We study the effects of strain on the electronic properties and persistent current characteristics o...
Dirac-like Hamiltonians, linear in momentum k, describe the low-energy physics of a large set of nov...
In this work, we study the graphene and its physical properties associated with the theory of the t...
The surfaces physics has attracted the attention of many researchers due to the discovery of materia...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
Because of Klein tunneling, electrostatic potentials are unable to confine Dirac electrons. We show ...
