8,625 research outputs found
Tight binding model for iron pnictides
We propose a five-band tight-binding model for the Fe-As layers of iron
pnictides with the hopping amplitudes calculated within the Slater-Koster
framework. The band structure found in DFT, including the orbital content of
the bands, is well reproduced using only four fitting parameters to determine
all the hopping amplitudes. The model allows to study the changes in the
electronic structure caused by a modification of the angle formed by
the Fe-As bonds and the Fe-plane and recovers the phenomenology previously
discussed in the literature. We also find that changes in modify the
shape and orbital content of the Fermi surface sheets.Comment: 12 pages, 6 eps figures. Figs 1 and 2 modified, minor changes in the
text. A few references adde
Optical conductivity and Raman scattering of iron superconductors
We discuss how to analyze the optical conductivity and Raman spectra of
multi-orbital systems using the velocity and the Raman vertices in a similar
way Raman vertices were used to disentangle nodal and antinodal regions in
cuprates. We apply this method to iron superconductors in the magnetic and
non-magnetic states, studied at the mean field level. We find that the
anisotropy in the optical conductivity at low frequencies reflects the
difference between the magnetic gaps at the X and Y electron pockets. Both gaps
are sampled by Raman spectroscopy. We also show that the Drude weight
anisotropy in the magnetic state is sensitive to small changes in the lattice
structure.Comment: 14 pages, 10 figures, as accepted in Phys. Rev. B,
explanations/discussion added in Secs. II, III and V
Resonance expansions in quantum mechanics
The goal of this contribution is to discuss various resonance expansions that
have been proposed in the literature.Comment: 10 pages and 1 figure; presented at the Istanbul workshop on
pseudo-Hermitian Hamiltonian
Competition between the Modulation Instability and Stimulated Brillouin Scattering in a Broadband Slow Light Device
We observe competition between the modulation instability (MI) and stimulated
Brillouin scattering (SBS) in a 9.2-GHz broadband SBS slow light device, in
which a standard 20-km-long single-mode LEAF fibre is used as the SBS medium.
We find that MI is dominant and depletes most of the pump power when we use an
intense pump beam at ~1.55 {\mu}m, where the LEAF fibre is anomalously
dispersive. The dominance of the MI in the LEAF-fibre-based system suppresses
the SBS gain, degrading the SBS slow light delay and limiting the SBS
gain-bandwidth to 126 dB \cdot GHz. In a dispersion-shifted highly nonlinear
fibre, the SBS slow light delay is improved due to the suppression of the MI,
resulting in a gain-bandwidth product of 344 dB \cdot GHz, limited by our
available pump power of 0.82 W
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