661 research outputs found
Theoretical study of angle-resolved two-photon photoemission in two-dimensional insulating cuprates
We propose angle-resolved two-photon photoemission spectroscopy (AR-2PPES) as
a technique to detect the location of the bottom of the upper Hubbard band
(UHB) in two-dimensional insulating cuprates. The AR-2PPES spectra are
numerically calculated for small Hubbard clusters. When the pump photon excites
an electron from the lower Hubbard band, the bottom of the UHB is less clear,
but when an electron in the nonbonding oxygen band is excited, the bottom of
the UHB can be identified clearly, accompanied with additional spectra
originated from the spin-wave excitation at half filling.Comment: 5 pages, 4 figure
Momentum Dependence of Resonant Inelastic X-Ray Scattering Spectrum in Insulating Cuprates
The resonant inelastic x-ray scattering spectrum in insulating cuprates is
examined by using the exact diagonalization technique on small clusters in the
two-dimensional Hubbard model with second and third neighbor hopping terms.
When the incident photon energy is tuned near the Cu K absorption edges, we
find that the features of the unoccupied upper Hubbard band can be extracted
from the spectrum through an anisotropic momentum dependence. They provide an
opportunity for the understanding of the different behavior of hole- and
electron-doped superconductors.Comment: 4 pages with 4 figures, to be published in PR
Electronic States in the Antiferromagnetic Phase of Electron-Doped High-Tc Cuprates
We investigate the electronic states in the antiferromagnetic (AF) phase of
electron-doped cuprates by using numerically exact diagonalization technique
for a t-t'-t''-J model. When AF correlation develops with decreasing
temperature, a gaplike behavior emerges in the optical conductivity.
Simultaneously, the coherent motion of carriers due to the same sublattice
hoppings is enhanced. We propose that the phase is characterized as an AF state
with small Fermi surface around the momentum k=(\pi,0) and (0,\pi). This is a
remarkable contrast to the behavior of hole-doped cuprates.Comment: RevTeX, 5 pages, 4 figures, to appear in Phys. Rev. B Brief Report
Angle-resolved photoemission in high Tc cuprates from theoretical viewpoints
The angle-resolved photoemission (ARPES) technique has been developed rapidly
over the last decay, accompanied by the improvement of energy and momentum
resolutions. This technique has been established as the most powerful tool to
investigate the high Tc cuprate superconductors. We review recent ARPES data on
the cuprates from a theoretical point of view, with emphasis on the systematic
evolution of the spectral weight near the momentum (pi,0) from insulator to
overdoped systems. The effects of charge stripes on the ARPES spectra are also
reviewed. Some recent experimental and theoretical efforts to understand the
superconducting state and the pseudogap phenomenon are discussed.Comment: Review, 25 pages, with 22 GIF figures. To appear in Supercond. Sci.
Technol. Vol. 13 April 2000. A version including PS figures can be found at
http://www.maekawa-lab.imr.tohoku.ac.jp/TOHYAMA/tohyama.ps.g
The short-range correlations of a doped Mott insulator
This paper presents numerical studies of the single hole tt't''J model that
address the interplay between the kinetic energy of itinerant electrons and the
exchange energy of local moments as of interest to doped Mott insulators. Due
to this interplay, two different spin correlations coexist around a mobile
vacancy. These local correlations provide an effective two-band picture that
explains the two-band structure observed in various theoretical and
experimental studies, the doping dependence of the momentum space anisotropic
pseudogap phenomena and the asymmetry between hole and electron doped cuprates.Comment: 8 pages, 3 figure
Nonlinear optical response and spin-charge separation in one-dimensional Mott insulators
We theoretically study the nonlinear optical response and photoexcited states
of the Mott insulators. The nonlinear optical susceptibility \chi^(3) is
calculated by using the exact diagonalization technique on small clusters. From
the systematic study of the dependence of \chi^(3) on dimensionality, we find
that the spin-charge separation plays a crucial role in enhancing \chi^(3) in
the one-dimensional (1D) Mott insulators. Based on this result, we propose a
holon-doublon model, which describes the nonlinear response in the 1D Mott
insulators. These findings show that the spin-charge separation will become a
key concept of optoelectronic devices.Comment: 5 pages with 3 figures, to appear in PRB RC, 15 August 200
Quasiparticles and c-axis coherent hopping in high T_c superconductors
We study the problem of the low-energy quasiparticle spectrum of the extended
t-J model and analyze the coherent hopping between weakly coupled planes
described by this model. Starting with a two-band model describing the Cu-O
planes and the unoccupied bands associated to the metallic atoms located in
between the planes, we obtain effective hopping matrix elements describing the
c-axis charge transfer. A computational study of these processes shows an
anomalously large charge anisotropy for doping concentrations around and below
the optimal doping.Comment: 4 pages, 3 figure
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