Bilayer graphene with single and multiple electrostatic barriers: Band structure and transmission
M Barbier, P Vasilopoulos, FM Peeters… - Physical Review B …, 2009 - APS
Physical Review B—Condensed Matter and Materials Physics, 2009•APS
We evaluate the electronic transmission and conductance in bilayer graphene through a
finite number of potential barriers. Further, we evaluate the dispersion relation in a bilayer
graphene superlattice with a periodic potential applied to both layers. As a model we use the
tight-binding Hamiltonian in the continuum approximation. For zero bias the dispersion
relation shows a finite gap for carriers with zero momentum in the direction parallel to the
barriers. This is in contrast to single-layer graphene where no such gap was found. A gap …
finite number of potential barriers. Further, we evaluate the dispersion relation in a bilayer
graphene superlattice with a periodic potential applied to both layers. As a model we use the
tight-binding Hamiltonian in the continuum approximation. For zero bias the dispersion
relation shows a finite gap for carriers with zero momentum in the direction parallel to the
barriers. This is in contrast to single-layer graphene where no such gap was found. A gap …
We evaluate the electronic transmission and conductance in bilayer graphene through a finite number of potential barriers. Further, we evaluate the dispersion relation in a bilayer graphene superlattice with a periodic potential applied to both layers. As a model we use the tight-binding Hamiltonian in the continuum approximation. For zero bias the dispersion relation shows a finite gap for carriers with zero momentum in the direction parallel to the barriers. This is in contrast to single-layer graphene where no such gap was found. A gap also appears for a finite bias. Numerical results for the energy spectrum, conductance, and the density of states are presented and contrasted with those pertaining to single-layer graphene.
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