116 research outputs found
Electromagnetic properties of viscous charged fluids
We provide a general theoretical framework to describe the electromagnetic
properties of viscous charged fluids, consisting for example of electrons in
certain solids or plasmas. We confirm that finite viscosity leads to multiple
modes of evanescent electromagnetic waves at a given frequency, one of which is
characterized by a negative index of refraction, as previously discussed in a
simplified model by one of the authors. In particular we explain how optical
spectroscopy can be used to probe the viscosity. We concentrate on the impact
of this on the coefficients of refraction and reflection at the sample-vacuum
interface. Analytical expressions are obtained relating the viscosity parameter
to the reflection and transmission coefficients of light. We demonstrate that
finite viscosity has the effect to decrease the reflectivity of a metallic
surface, while the electromagnetic field penetrates more deeply. While on a
phenomenological level there are similarities to the anomalous skin effect, the
model presented here requires no particular assumptions regarding the
corpuscular nature of the charge liquid. A striking consequence of the
branching phenomenon into two degenerate modes is the occurrence in a
half-infinite sample of oscillations of the electromagnetic field intensity as
a function of distance from the interface.Comment: 12 pages, 5 figure
Can dd excitations mediate pairing ?
The Cu- states in the high- cuprates are often described as a single
band of states, with the other four states having about 2
to 3 eV higher energy due to the lower-than-octahedral crystal field at the
copper sites. However, excitations to these higher energy states observed with
RIXS show indications of strong coupling to doped holes in the
band. This relaunches a decades-old question of the possible role of the
orbital degrees of freedom that once motivated Bednorz and M\"uller to search
for superconductivity in these systems. Here we explore a direction different
from the Jahn-Teller electron-phonon coupling considered by Bednorz and
M\"uller, namely the interaction between holes mediated by excitations.Comment: 6 pages, 4 figure
Magnetoplasmon resonances in polycrystalline bismuth as seen via terahertz spectroscopy
We report the magnetic field-dependent far-infrared reflectivity of
polycrystalline bismuth. We observe four distinct absorptions that we attribute
to magnetoplasmon resonances, which are collective modes of an electron-hole
liquid in magnetic field and become optical and acoustic resonances of the
electron-hole system in the small-field limit. The acoustic mode is expected
only when the masses of distinct components are very different, which is the
case in bismuth. In a polycrystal, where the translational symmetry is broken,
a big shift of spectral weight to acoustic plasmon is possible. This enables us
to detect an associated plasma edge. Although the polycrystal sample has grains
of randomly distributed orientations, our reflectivity results can be explained
by invoking only two, clearly distinct, series of resonances. In the limit of
zero field, the optical modes of these two series converge onto plasma
frequencies measured in monocrystal along the main optical axes.Comment: Accepted in PR
Non-Drude universal scaling laws for the optical response of local Fermi liquids
We investigate the frequency and temperature dependence of the low-energy
electron dynamics in a Landau Fermi liquid with a local self-energy. We show
that the frequency and temperature dependencies of the optical conductivity
obey universal scaling forms, for which explicit analytical expressions are
obtained. For the optical conductivity and the associated memory function, we
obtain a number of surprising features that differ qualitatively from the Drude
model and are universal characteristics of a Fermi liquid. Different physical
regimes of scaling are identified, with marked non-Drude features in the regime
where hbar omega ~ kB T. These analytical results for the optical conductivity
are compared to numerical calculations for the doped Hubbard model within
dynamical mean-field theory. For the "universal" low-energy electrodynamics, we
obtain perfect agreement between numerical calculations and analytical scaling
laws. Both results show that the optical conductivity displays a non-Drude
"foot", which could be easily mistaken as a signature of breakdown of the Fermi
liquid, while it actually is a striking signature of its applicability. The
aforementioned scaling laws provide a quantitative tool for the experimental
identification and analysis of the Fermi-liquid state using optical
spectroscopy, and a powerful method for the identification of alternative
states of matter, when applicable.Comment: Published versio
Optical properties of Bi2Te2Se at ambient and high pressure
The temperature dependence of the complex optical properties of the
three-dimensional topological insulator Bi2Te2Se is reported for light
polarized in the a-b planes at ambient pressure, as well as the effects of
pressure at room temperature. This material displays a semiconducting character
with a bulk optical gap of 300 meV at 295 K. In addition to the two expected
infrared-active vibrations observed in the planes, there is additional fine
structure that is attributed to either the removal of degeneracy or the
activation of Raman modes due to disorder. A strong impurity band located at
200 cm^{-1} is also observed. At and just above the optical gap, several
interband absorptions are found to show a strong temperature and pressure
dependence. As the temperature is lowered these features increase in strength
and harden. The application of pressure leads to a very abrupt closing of the
gap above 8 GPa, and strongly modifies the interband absorptions in the
mid-infrared spectral range. While ab initio calculations fail to predict the
collapse of the gap, they do successfully describe the size of the band gap at
ambient pressure, and the magnitude and shape of the optical conductivity.Comment: 8 pages, 7 figure
High sensitivity variable-temperature infrared nanoscopy of conducting oxide interfaces
Probing the local transport properties of two-dimensional electron systems
(2DES) confined at buried interfaces requires a non-invasive technique with a
high spatial resolution operating in a broad temperature range. In this paper,
we investigate the scattering-type scanning near field optical microscopy as a
tool for studying the conducting LaAlO3/SrTiO3 interface from room temperature
down to 6 K. We show that the near-field optical signal, in particular its
phase component, is highly sensitive to the transport properties of the
electron system present at the interface. Our modelling reveals that such
sensitivity originates from the interaction of the AFM tip with coupled
plasmon-phonon modes with a small penetration depth. The model allows us to
quantitatively correlate changes in the optical signal with the variation of
the 2DES transport properties induced by cooling and by electrostatic gating.
To probe the spatial resolution of the technique, we image conducting
nano-channels written in insulating heterostructures with a voltage-biased tip
of an atomic force microscope.Comment: 19 pages, 5 figure
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