81 research outputs found
Spin pumping and magnetization dynamics in ferromagnet-Luttinger liquid junctions
We study spin transport between a ferromagnet with time-dependent
magnetization and a conducting carbon nanotube or quantum wire, modeled as a
Luttinger liquid. The precession of the magnetization vector of the ferromagnet
due for instance to an outside applied magnetic field causes spin pumping into
an adjacent conductor. Conversely, the spin injection causes increased
magnetization damping in the ferromagnet. We find that, if the conductor
adjacent to the ferromagnet is a Luttinger liquid, spin pumping/damping is
suppressed by interactions, and the suppression has clear Luttinger liquid
power law temperature dependence. We apply our result to a few particular
setups. First we study the effective Landau-Lifshitz-Gilbert (LLG) coupled
equations for the magnetization vectors of the two ferromagnets in a FM-LL-FM
junction. Also, we compute the Gilbert damping for a FM-LL and a FM-LL-metal
junction.Comment: 7 pages, 3 figures, RevTex
Dirac point metamorphosis from third-neighbor couplings in graphene
We study the band structure and the density of states of graphene in the
presence of a next-to-nearest-neighbor coupling (N2) and a
third-nearest-neighbor coupling (N3). We show that for values of N3 larger or
equal to 1/3 of the value of the nearest-neighbor hopping (NN), extra Dirac
points appear in the spectrum. If N3 is exactly equal to 1/3 NN, the new Dirac
points are localized at the M points of the Brillouin zone and are hybrid: the
electrons have a linear dispersion along the GammaM direction and a quadratic
dispersion along the perpendicular direction MK. For larger values of N3 the
new points have a linear dispersion, and are situated along the MK line. For a
value of N3 equal to 1/2 NN, these points merge with the Dirac cones at the K
points, yielding a gapless quadratic dispersion around K, while for larger
values each quadratic point at K splits again into four Dirac points. The
effects of changing the N2 coupling are not so dramatic. We calculate the
density of states and we show that increasing the N3 coupling lowers the energy
of the Van Hove singularities, and when N3 is larger than 1/3 NN the Van Hove
singularities split in two, giving rise to extra singularities at low energies.Comment: 13 pages, 10 figure
Effect of a single impurity on the local density of states in monolayer and bilayer graphene
We use the T-matrix approximation to analyze the effect of a localized
impurity on the local density of states in mono- and bilayer graphene. For
monolayer graphene the Friedel oscillations generated by intranodal scattering
obey an inverse-square law, while the internodal ones obey an inverse law. In
the Fourier transform this translates into a filled circle of high intensity in
the center of the Brillouin zone, and empty circular contours around its
corners. For bilayer graphene both types of oscillations obey an inverse law.Comment: 8 pages, 3 figures, version accepted for publicatio
Quasiparticle scattering and local density of states in graphite
We determine the effect of quasiparticle interference on the spatial
variations of the local density of states (LDOS) in graphite in the
neighborhood of an isolated impurity. A number of characteristic behaviors of
interference are identified in the Fourier transformed spectrum. A comparison
between our results and scanning tunneling microscopy (STM) experiments could
provide a critical test of the range (of energy) of applicability of the Fermi
liquid description of graphite, where some evidence of the breakdown of Fermi
liquid theory has recently been discussed. Moreover, given the similarity
between the band structures of graphite and that of nodal quasiparticles in a
d-wave superconductor, a comparison between results in the two materials is
useful for understanding the physics of the cuprates.Comment: 5 pages, 4 figures, RevTex
Characterizing unconventional superconductors from the spin structure of impurity-induced bound states
Cooper pairs in two-dimensional unconventional superconductors with broken
inversion symmetry are in a mixture of an even-parity spin-singlet pairing
state with an odd-parity spin-triplet pairing state. We study the magnetic
properties of the impurity bound states in such superconductors and find
striking signatures in their spin polarization which allow to unambiguously
discriminate a non-topological superconducting phase from a topological one.
Moreover, we show how these properties, which could be measured using
spin-polarized scanning tunneling microscopy (STM), also enable to determine
the direction of the spin-triplet pairing vector of the host material and thus
to distinguish between different types of unconventional pairing.Comment: 11 pages + 9 pages of supplementary information, 9 figures + 8
figures (SI
The local density of states in the presence of impurity scattering in graphene at high magnetic field
We study the Fourier transform of the local density of states (LDOS) in
graphene in the presence of a single impurity at high magnetic field. We find
that the most pronounced features occur for energies of the STM tip matching
the Landau level energies. The Fourier transform of the LDOS shows regions of
high intensity centered around the center and the corners of the Brillouin zone
(BZ). The radial intensity dependence of these features is determined by the
form of the wavefunctions of the electrons in the quantum Hall regime.
Moreover, some of these regions break rotational symmetry, and their angular
dependence is determined by the chirality of the graphene electrons. For the
zeroth Landau level, the ratio between the features at the corners and center
of the BZ depends on the nature of the disorder: it goes to zero for potential
disorder, and is finite for hopping disorder. We believe that a comparison
between our analysis and experiments will help understand the form of the
quasiparticle wavefunction, as well as the nature of disorder in graphene.Comment: 12 pages, 4 figure
Asymptotic behavior of impurity-induced bound states in low-dimensional topological superconductors
We study theoretically the asymptotic behavior of the Shiba bound states
associated with magnetic impurities embedded in both 2D and 1D anomalous
superconductors. We calculate analytically the spatial dependence of the local
density of states together with the spin polarization associated with the Shiba
bound states. We show that the latter quantity exhibits drastic differences
between s-wave and different types of p-wave superconductors. Such properties,
which could be measured using spin-polarized STM, offer therefore a way to
discriminate between singlet and triplet pairing in low-dimensional
superconductors, as well as a way to estimate the amplitude of the triplet
pairing in these systems.Comment: 18 pages, 5 figure
The complete impurity scattering formalism in graphene
We present the complete formalism that describes scattering in graphene at
low-energies. We begin by analyzing the real-space free Green's function
matrix, and its analytical expansions at low-energy, carefully incorporating
the discrete lattice structure, and arbitrary forms of the atomic-orbital wave
function. We then compute the real-space Green's function in the presence of an
impurity. We express our results both in 2X2 and 4X4 forms (for the two
sublattices and the two inequivalent valleys of the first Brillouin zone). We
compare this with the 4X4 formalism proposed in cond-mat/0608228 and
cond-mat/0702019, and show that the latter is incomplete. We describe how it
can be adapted to accurately take into account the effects of inter-valley
scattering on spatially-varying quantities such as the local density of states.Comment: 11 pages, 1 figur
Friedel oscillations at the Dirac-cone-merging point in anisotropic graphene
We study the Friedel oscillations induced by a localized impurity in
anisotropic graphene. We focus on the limit when the two inequivalent Dirac
points merge. We find that in this limit the Friedel oscillations manifest very
peculiar features, such as a strong asymmetry and an atypical inverse
square-root decay. Our calculations are performed using both a T-matrix
approximation and a tight-binding exact diagonalization technique. They allow
us to obtain numerically the local density of states as a function of energy
and position, as well as an analytical form of the Friedel oscillations in the
continuum limit. The two techniques yield results that are in excellent
agreement, confirming the accuracy of such methods to approach this problem
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