2,484 research outputs found
Valley symmetry breaking in bilayer graphene: a test to the minimal model
Physical properties reflecting valley asymmetry of Landau levels in a biased
bilayer graphene under magnetic field are discussed. Within the band
continuum model with Hartree-corrected self-consistent gap and finite damping
factor we predict the appearance of anomalous steps in quantized Hall
conductivity due to the degeneracy lifting of Landau levels. Moreover, the
valley symmetry breaking effect appears as a non-semiclassical de Haas-van
Alphen effect where the reduction of the oscillation period to half cannot be
accounted for through quasi-classical quantization of the orbits in reciprocal
space, still valley degenerate.Comment: 4 pages, 3 figure
Quantum quench dynamics and population inversion in bilayer graphene
The gap in bilayer graphene (BLG) can directly be controlled by a
perpendicular electric field. By tuning the field through zero at a finite rate
in neutral BLG, excited states are produced. Due to screening, the resulting
dynamics is determined by coupled non-linear Landau-Zener models. The generated
defect density agrees with Kibble-Zurek theory in the presence of subleading
logarithmic corrections. After the quench, population inversion occurs for
wavevectors close to the Dirac point. This could, at least in principle provide
a coherent source of infra-red radiation with tunable spectral properties
(frequency and broadening). Cold atoms with quadratic band crossing exhibit the
same dynamics.Comment: 6 pages, 2 figures, 1 tabl
Dirac points merging and wandering in a model Chern insulator
We present a model for a Chern insulator on the square lattice with complex
first and second neighbor hoppings and a sublattice potential which displays an
unexpectedly rich physics. Similarly to the celebrated Haldane model, the
proposed Chern insulator has two topologically non-trivial phases with Chern
numbers . As a distinctive feature of the present model, phase
transitions are associated to Dirac points that can move, merge and split in
momentum space, at odds with Haldane's Chern insulator where Dirac points are
bound to the corners of the hexagonal Brillouin zone. Additionally, the
obtained phase diagram reveals a peculiar phase transition line between two
distinct topological phases, in contrast to the Haldane model where such
transition is reduced to a point with zero sublattice potential. The model is
amenable to be simulated in optical lattices, facilitating the study of phase
transitions between two distinct topological phases and the experimental
analysis of Dirac points merging and wandering
Algebraic solution of a graphene layer in a transverse electric and perpendicular magnetic fields
We present an exact algebraic solution of a single graphene plane in
transverse electric and perpendicular magnetic fields. The method presented
gives both the eigen-values and the eigen-functions of the graphene plane. It
is shown that the eigen-states of the problem can be casted in terms of
coherent states, which appears in a natural way from the formalism.Comment: 11 pages, 5 figures, accepted for publication in Journal of Physics
Condensed Matte
The role of pressure on the magnetism of bilayer graphene
We study the effect of pressure on the localized magnetic moments induced by
vacancies in bilayer graphene in the presence of topological defects breaking
the bipartite nature of the lattice. By using a mean-field Hubbard model we
address the two inequivalent types of vacancies that appear in the Bernal
stacking bilayer graphene. We find that by applying pressure in the direction
perpendicular to the layers the critical value of the Hubbard interaction
needed to polarize the system decreases. The effect is particularly enhanced
for one type of vacancies, and admits straightforward generalization to
multilayer graphene in Bernal stacking and graphite. The present results
clearly demonstrate that the magnetic behavior of multilayer graphene can be
affected by mechanical transverse deformation
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