47,600 research outputs found
Plasmons and near-field amplification in double-layer graphene
We study the optical properties of double-layer graphene for linearly
polarized evanescent modes and discuss the in-phase and out-of-phase plasmon
modes for both, longitudinal and transverse polarization. We find a energy for
which reflection is zero, leading to exponentially amplified transmitted modes
similar to what happens in left-handed materials. For layers with equal
densities cm, we find a typical layer separation of
m to detect this amplification for transverse polarization
which may serve as an indirect observation of transverse plasmons. When the two
graphene layers lie on different chemical potentials, the exponential
amplification either follows the in-phase or out-of-phase plasmon mode
depending on the order of the low- and high-density layer. This opens up the
possibility of a tunable near-field amplifier or switch.Comment: 9 pages, 8 figure
Plasmonics in topological insulators: Spin-charge separation, the influence of the inversion layer, and phonon-plasmon coupling
We demonstrate via three examples that topological insulators (TI) offer a
new platform for plasmonics. First, we show that the collective excitations of
a thin slab of a TI display spin-charge separation. This gives rise to purely
charge-like optical and purely spin-like acoustic plasmons, respectively.
Second, we argue that the depletion layer mixes Dirac and Schr\"odinger
electrons which can lead to novel features such as high modulation depths and
interband plasmons. The analysis is based on an extension of the usual formula
for optical plasmons that depends on the slab width and on the dielectric
constant of the TI. Third, we discuss the coupling of the TI surface phonons to
the plasmons and find strong hybridisation especially for samples with large
slab widths.Comment: 37 pages, 7 figure
Spin-charge separation of plasmonic excitations in thin topological insulators
We discuss plasmonic excitations in a thin slab of a topological insulators.
In the limit of no hybridization of the surface states and same electronic
density of the two layers, the electrostatic coupling between the top and
bottom layers leads to optical and acoustic plasmons which are purely charge
and spin collective oscillations. We then argue that a recent experiment on the
plasmonic excitations of Bi2Se3 [Di Pietro et al, Nat. Nanotechnol. 8, 556
(2013)] must be explained by including the charge response of the
two-dimensional electron gas of the depletion layer underneath the two
surfaces. We also present an analytic formula to fit their data.Comment: 7 pages, 5 figure
Exploring spin-orbital models with dipolar fermions in zig-zag optical lattices
Ultra-cold dipolar spinor fermions in zig-zag type optical lattices can mimic
spin-orbital models relevant in solid-state systems, as transition-metal oxides
with partially filled d-levels, with the interesting advantage of reviving the
quantum nature of orbital fluctuations. We discuss two different physical
systems in which these models may be simulated, showing that the interplay
between lattice geometry and spin-orbital quantum dynamics produces a wealth of
novel quantum phases.Comment: 4 pages + supplementary materia
Exclusive photoproduction of quarkonium in proton-nucleus collisions at energies available at the CERN Large Hadron Collider
In this work we investigate the coherent photoproduction of psi(1S), psi(2S)
and Upsilon (1S) states in the proton-nucleus collisions in the LHC energies.
Predictions for the rapidity distributions are presented using the color dipole
formalism and including saturation effects that are expected to be relevant at
high energies. Calculations are done at the energy 5.02 TeV and also for the
next LHC run at 8.8 TeV in proton-lead mode. Discussion is performed on the
main theoretical uncertainties associated to the calculations.Comment: 05 pages, 5 figures. Version to be published in Phys. Rev.
Light vector meson photoproduction in hadron-hadron and nucleus-nucleus collisions at the energies available at the CERN Large Hadron Collider
In this work we analyse the theoretical uncertainties on the predictions for
the photoproduction of light vector mesons in coherent pp, pA and AA collisions
at the LHC energies using the color dipole approach. In particular, we present
our predictions for the rapidity distribution for rh0 and phi photoproduction
and perform an analysis on the uncertainties associated to the choice of vector
meson wavefunctionand the phenomenological models for the dipole cross section.
Comparison is done with the recent ALICE analysis on coherent production of rho
at 2.76 TeV in PbPb collisions.Comment: 07 pages, 6 figures. Version to be published in Phys. Rev.
Diffractive dissociation in proton-nucleus collisions at collider energies
The cross section for the nuclear diffractive dissociation in proton-lead
collisions at the LHC is estimated. Based on the current theoretical
uncertainties for the single (target) diffactive cross section in hadron-hadron
reactions one obtains sigma_SD(5.02 TeV) = 19.67 \pm 5.41 mb and sigma_SD(8.8
TeV) = 18.76 \pm 5.77 mb, respectively. The invariant mass M_X for the reaction
pPb -> pX is also analyzed. Discussion is performed on the main theoretical
uncertainties associated to the calculations.Comment: 04 pages, 2 figures. Final version to be published in European
Physical Journal A - "Hadrons and Nuclei
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