393 research outputs found
Optical Properties of TiN Thin Films close to the Superconductor-Insulator Transition
We present the intrinsic optical properties over a broad spectral range of
TiN thin films deposited on a Si/SiO substrate. We analyze the measured
reflectivity spectra of the film-substrate multilayer structure within a
well-establish procedure based on the Fresnel equation and extract the real
part of the optical conductivity of TiN. We identify the metallic contribution
as well as the finite energy excitations and disentangle the spectral weight
distribution among them. The absorption spectrum of TiN bears some similarities
with the electrodynamic response observed in the normal state of the
high-temperature superconductors. Particularly, a mid-infrared feature in the
optical conductivity is quite reminiscent of a pseudogap-like excitation
Dynamics of disordered heavy Fermion systems
Dynamics of the disordered heavy Fermion model of Dobrosavljevic et al. are
calculated using an expression for the spectral function of the Anderson model
which is consistent with quantum Monte Carlo results. We compute the
self-energy for three distributions of Kondo scales including the distribution
of Bernal et al. for UCu{5-x}Pd{x}. The corresponding low temperature optical
conductivity shows a low-frequency pseudogap, a negative optical mass
enhancement, and a linear in frequency transport scattering rate, consistent
with results in Y{1-x}U{x}Pd{3} and UCu{5-x}Pd{x}.Comment: 5 pages, LaTeX and 4 PS figure
Electronic Structure and Charge Dynamics of Huesler Alloy Fe2TiSn Probed by Infrared and Optical Spectroscopy
We report on the electrodynamics of a Heusler alloy Fe2TiSn probed over four
decades in energy: from the far infrared to the ultraviolet. Our results do not
support the suggestion of Kondo-lattice behavior inferred from specific heat
measurements. Instead, we find a conventional Drude-like response of free
carriers, with two additional absorption bands centered at around 0.1 and 0.87
eV. The latter feature can be interpreted as excitations across a pseudogap, in
accord with band structure calculations.Comment: 3 pages, 4 figure
Optical Properties of Heavy Fermion Systems with SDW Order
The dynamical conductivity , reflectivity , and
tunneling density of states of strongly correlated systems (like
heavy fermions) with a spin-density wave (SDW) magnetic order are studied as a
function of impurity scattering rate and temperature. The theory is generalized
to include strong coupling effects in the SDW order. The results are discussed
in the light of optical experiments on heavy-fermion SDW materials. With some
modifications the proposed theory is applicable also to heavy fermions with
localized antiferromagnetic (LAF) order.Comment: 9 pages, 10 figure
Optical Probing of Thermal Lattice Fluctuations in Charge-Density-Wave Condensates
Thermal lattice fluctuations in charge-density-wave (CDW) condensates have been studied by means of optical investigations on the prototype CDW compound K0.3MoO3 and its alloys. The temperature dependence of the CDW gap absorption in the mid-IR frequency range is strongly indicative of the important role played by the thermal lattice fluctuation effects. The latter remove the inverse-square-root singularity, expected for the case of the static distorted lattice. In fact, a considerable broadening (i.e., larger than k(B)T) of the subgap tail absorption is found by increasing the temperature towards T(CDW). Moreover, we find that the phase phonon modes also give an important contribution to the disorder parameter, thus being an essential ingredient for the thermal fluctuation effects
Effective-Medium Theory for the Normal State in Orientationally Disordered Fullerides
An effective-medium theory for studying the electronic structure of the
orientationally disordered A3C60 fullerides is developed and applied to study
various normal-state properties. The theory is based on a cluster-Bethe-lattice
method in which the disordered medium is modelled by a three-band Bethe
lattice, into which we embed a molecular cluster whose scattering properties
are treated exactly. Various single-particle properties and the
frequency-dependent conductivity are calculated in this model, and comparison
is made with numerical calculations for disordered lattices, and with
experiment.Comment: 12 pages + 2 figures, REVTeX 3.
Magneto-optical behaviour of EuIn_2P_2
We report results of a magneto-optical investigation of the Zintl-phase
compound EuInP. The compound orders magnetically at =24 K and
exhibits concomitant large magnetoresistance effects. For 50 K and
increasing magnetic fields we observe a transfer of spectral weight in
from energies above 1 eV into the low-energy metallic
component as well as into a mid-infrared signal centered at about 600
cm. This latter absorption is reminiscent to what has been seen in a
large variety of so-called Kondo materials and ascribed to excitations across
the hybridization gap. The observed gain of Drude weight upon increasing
magnetic field suggests an enhancement of the itinerant charge-carrier
concentration due to the increasing magnetization, a phenomenon that was
previously observed in other compounds which exhibit colossal magnetoresistive
effects.Comment: 13 pages, 4 figure
Electronic correlations in iron-pnictide superconductors and beyond; what can we learn from optics
The Coulomb repulsion, impeding electrons' motion, has an important impact on
the charge dynamics. It mainly causes a reduction of the effective metallic
Drude weight (proportional to the so-called optical kinetic energy),
encountered in the optical conductivity, with respect to the expectation within
the nearly-free electron limit (defining the so-called band kinetic energy), as
evinced from band-structure theory. In principle, the ratio between the optical
and band kinetic energy allows defining the degree of electronic correlations.
Through spectral weight arguments based on the excitation spectrum, we provide
an experimental tool, free from any theoretical or band-structure based
assumptions, in order to estimate the degree of electronic correlations in
several systems. We first address the novel iron-pnictide superconductors,
which serve to set the stage for our approach. We then revisit a large variety
of materials, ranging from superconductors, to Kondo-like systems as well as
materials close to the Mott-insulating state. As comparison we also tackle
materials, where the electron-phonon coupling dominates. We establish a direct
relationship between the strength of interaction and the resulting reduction of
the optical kinetic energy of the itinerant charge carriers
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