719 research outputs found
Interplay of superconductivity and magnetism in strong coupling
A model is introduced describing the interplay between superconductivity and
spin-ordering. It is characterized by on-site repulsive electron-electron
interactions, causing antiferromagnetism, and nearest-neighbor attractive
interactions, giving rise to d-wave superconductivity. Due to a special choice
for the lattice, this model has a strong-coupling limit where the
superconductivity can be described by a bosonic theory, similar to the strongly
coupled negative U Hubbard model. This limit is analyzed in the present paper.
A rich mean-field phase diagram is found and the leading quantum corrections to
the mean-field results are calculated. The first-order line between the
antiferromagnetic- and the superconducting phase is found to terminate at a
tricritical point, where two second-order lines originate. At these lines, the
system undergoes a transition to- and from a phase exhibiting both
antiferromagnetic order and superconductivity. At finite temperatures above the
spin-disordering line, quantum-critical behavior is found. For specific values
of the model parameters, it is possible to obtain SO(5) symmetry involving the
spin- and the phase-sector at the tricritical point. Although this symmetry is
explicitly broken by the projection to the lower Hubbard band, it survives on
the mean-field level, and modes related to a spontaneously broken SO(5)
symmetry are present on the level of the random phase approximation in the
superconducting phase.Comment: 16 pages Revtex, 5 figure
Quantum disordered phase in a doped antiferromagnet
A quantitative description of the transition to a quantum disordered phase in
a doped antiferromagnet is obtained with a U(1) gauge-theory, where the gap in
the spin-wave spectrum determines the strength of the gauge-fields. They
mediate an attractive long-range interaction whose possible bound-states
correspond to charge-spin separation and pairing.Comment: 11 pages, LaTex, chris-preprint-1994-
Populated Domain Walls
Several experiments suggest that the charge carriers in the normal state of
certain cuprate superconductors reside on domain walls. In an earlier paper, we
suggested that several aspects of the anomalous dynamical behavior of these
materials could be explained, at least qualitatively, on this basis. Here,
using results on the ground state energy of the 1-dimensional Hubbard model
(soluble by Bethe ansatz techniques) as a function of charge density, we argue
that a non-zero charge density localized to domain walls is a very plausible
consequence of strong short-range electron-electron repulsion. We also suggest
a method to suppress meandering of the walls, and thereby enhance their
signature in neutron diffraction.Comment: Minor Corrections, References added, Phyzzx, 10 pg
The gas of elastic quantum strings in 2+1 dimensions: finite temperatures
The finite temperature physics of the gas of elastic quantum strings as
introduced in J. Zaanen, Phys. Rev. Lett. 84, 753 is investigated. This model
is inspired on the stripes in the high Tc superconductors. We analyze in detail
how the kinetic interactions of the zero temperature quantum problem crossover
into the entropic interactions of the high temperature limit.Comment: 14 pages, 2 figure
Periodic Coherence Peak Height Modulations in Superconducting BSCCO
In this paper we analyze, using scanning tunneling spectroscopy (STS), the
local density of electronic states (LDOS) in nearly optimally doped BSCCO in
zero field. We see both dispersive and non-dispersive spatial LDOS modulations
as a function of energy in our samples. Moreover, a spatial map of the
superconducting coherence peak heights shows the same structure as the low
energy LDOS. This suggests that these non-dispersive LDOS modulations originate
from an underlying charge-density modulation which interacts with
superconductivity.Comment: 8 pages, 5 figures with 15 total eps file
Dimerization versus Orbital Moment Ordering in the Mott insulator YVO
We use exact diagonalization combined with mean-field theory to investigate
the phase diagram of the spin-orbital model for cubic vanadates. The spin-orbit
coupling competes with Hund's exchange and triggers a novel phase, with the
ordering of orbital magnetic moments stabilized by the tilting of
VO octahedra. It explains qualitatively spin canting and reduction of
magnetization observed in YVO. At finite temperature an orbital Peierls
instability in the -type antiferromagnetic phase induces modulation of
magnetic exchange constants even in absence of lattice distortions. The
calculated spin structure factor shows a magnon splitting due to the orbital
Peierls dimerization.Comment: 4 pages, 5 figures, Revte
On the relation between decoherence and spontaneous symmetry breaking
We have recently shown that there is a limit to quantum coherence in
many-particle spin qubits due to spontaneous symmetry breaking. These results
were derived for the Lieb-Mattis spin model. Here we will show that the
underlying mechanism of decoherence in systems with spontaneous symmetry
breaking is in fact more general. We present here a generic route to finding
the decoherence time associated with spontaneous symmetry breaking in many
particle qubits, and subsequently we apply this approach to two model systems,
indicating how the continuous symmetries in these models are spontaneously
broken and discussing the relation of this symmetry breaking to the thin
spectrum. We then present in detail the calculations that lead to the limit to
quantum coherence, which is due to energy shifts in the thin spectrum.Comment: 14 pages, 5 figure
Striped phases in the two-dimensional Hubbard model with long-range Coulomb interaction
We investigate the formation of partially filled domain walls in the
two-dimensional Hubbard model in the presence of long-range interaction. Using
an unrestricted Gutzwiller variational approach we show that: i) the strong
local interaction favors charge segregation in stripe domain walls; ii) The
long-range interaction favors the formation of half-filled vertical stripes
with a period doubling due to the charge and a period quadrupling due to the
spins along the wall. Our results show that, besides the underlying lattice
structure, also the electronic interactions can contribute to determine the
different domain wall textures in Nd doped copper oxides and nickel oxides
Combined density-functional and dynamical cluster quantum Monte Carlo calculations for three-band Hubbard models for hole-doped cuprate superconductors
Using a combined local density functional theory (LDA-DFT) and quantum Monte
Carlo (QMC) dynamic cluster approximation approach, the parameter dependence of
the superconducting transition temperature Tc of several single-layer
hole-doped cuprate superconductors with experimentally very different Tcmax is
investigated. The parameters of two different three-band Hubbard models are
obtained using the LDA and the downfolding Nth-order muffin-tin orbital
technique with N=0 and 1 respectively. QMC calculations on 4-site clusters show
that the d-wave transition temperature Tc depends sensitively on the
parameters. While the N=1 MTO basis set which reproduces all three
bands leads to a d-wave transition, the N=0 set which merely reproduces the LDA
Fermi surface and velocities does not
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