115 research outputs found
Optical Conductivity of the t-J model within Cluster Dynamical Mean Field Theory
We study the evolution of the optical conductivity in the t-J model with
temperature and doping using the Extended Dynamical Cluster Approximation. The
cluster approach results in an optical mass which is doping independent near
half filling. The transition to the superconducting state in the overdoped
regime is characterized by a decrease in the hole kinetic energy, in contrast
to the underdoped side where kinetic energy of holes increases upon superfluid
condensation. In both regimes, the optical conductivity displays anomalous
transfers of spectral weight over a broad frequency region.Comment: 4 pages, 3 figure
Complex Landau Ginzburg Theory of the Hidden Order in URu_2Si_2
We develop a Landau Ginzburg theory of the hidden order phase and the local
moment antiferromagnetic phase of URu_2Si_2. We unify the two broken symmetries
in a common complex order parameter and derive many experimentally relevant
consequences such as the topology of the phase diagram in magnetic field and
pressure. The theory accounts for the appearance of a moment under application
of stress and the thermal expansion anomaly across the phase transitions. It
identifies the low energy mode which is seen in the hidden order phase near the
conmensurate wavector (0,0, 1) as the pseudo-Goldstone mode of the approximate
U(1) symmetry.Comment: 4 pages, 3 figure
Quantum Monte Carlo Impurity Solver for Cluster DMFT and Electronic Structure Calculations in Adjustable Base
We generalized the recently introduced new impurity solver based on the
diagrammatic expansion around the atomic limit and Quantum Monte Carlo
summation of the diagrams. We present generalization to the cluster of
impurities, which is at the heart of the cluster Dynamical Mean-Field methods,
and to realistic multiplet structure of a correlated atom, which will allow a
high precision study of actinide and lanthanide based compounds with the
combination of the Dynamical Mean-Field theory and band structure methods. The
approach is applied to both, the two dimensional Hubbard and t-J model within
Cellular Dynamical Mean Field method. The efficient implementation of the new
algorithm, which we describe in detail, allows us to study coherence of the
system at low temperature from the underdoped to overdoped regime. We show that
the point of maximal superconducting transition temperature coincides with the
point of maximum scattering rate although this optimal doped point appears at
different electron densities in the two models. The power of the method is
further demonstrated on the example of the Kondo volume collapse transition in
Cerium. The valence histogram of the DMFT solution is presented showing the
importance of the multiplet splitting of the atomic states.Comment: 12 pages, 4 figure
Mott Transition and Magnetism in Rare Earth Nickelates and its Fingerprint on the X-ray Scattering
The metal-insulator transition (MIT) remains among the most thoroughly
studied phenomena in solid state physics, but the complexity of the phenomena,
which usually involves cooperation of many degrees of freedom including
orbitals, fluctuating local moments, magnetism, and the crystal structure, have
resisted predictive ab-initio treatment. Here we develop ab-initio theoretical
method for correlated electron materials, based on Dynamical Mean Field Theory,
which can predict the change of the crystal structure across the MIT at finite
temperature. This allows us to study the coupling between electronic, magnetic
and orbital degrees of freedom with the crystal structure across the MIT in
rare-earth nickelates. We predict the free energy profile of the competing
states, and the theoretical magnetic ground state configuration, which is in
agreement with neutron scattering data, but is different from the magnetic
models proposed before. The resonant elastic X-ray response at the K-edge,
which was argued to be a direct probe of the charge order, is theoretically
modelled within the Dynamical Mean Field Theory, including the core-hole
interaction. We show that the line-shape of the measured resonant elastic X-ray
response can be explained with the "site-selective" Mott scenario without real
charge order on Ni sites.Comment: Acknowledgments updated, citations adde
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