38 research outputs found
Charge-density wave formation in Sr_{14}Cu_{24}O_{41}
The electrodynamic response of the spin-ladder compound
SrCaCuO () has been studied from
radiofrequencies up to the infrared. At temperatures below 250 K a pronounced
absorption peak appears around 12 cm in SrCuO for
the radiation polarized along the chains/ladders ().
In addition a strongly temperature dependent dielectric relaxation is observed
in the kHz - MHz range. We explain this behavior by a charge density wave which
develops in the ladders sub-system and produces a mode pinned at 12 cm.
With increasing Ca doping the mode shifts up in frequency and eventually
disappears for because the dimensionality of the system crosses over from
one to two dimensions, giving way to the superconducting ground state under
pressure.Comment: One name added to author list 4 pages, 2 figures, email:
[email protected]
Signatures of polaronic excitations in quasi-one-dimensional LaTiO
The optical properties of quasi-one-dimensional metallic LaTiO are
studied for the polarization along the and axes. With decreasing
temperature modes appear along both directions suggestive for a phase
transition. The broadness of these modes along the conducting axis might be due
to the coupling of the phonons to low-energy electronic excitations across an
energy gap. We observe a pronounced midinfrared band with a temperature
dependence consistent with (interacting) polaron models. The polaronic picture
is corroborated by the presence of strong electron-phonon coupling and the
temperature dependence of the dc conductivity.Comment: 5 pages, 5 figure
Ordering phenomena in quasi one-dimensional organic conductors
Low-dimensional organic conductors could establish themselves as model
systems for the investigation of the physics in reduced dimensions. In the
metallic state of a one-dimensional solid, Fermi-liquid theory breaks down and
spin and charge degrees of freedom become separated. But the metallic phase is
not stable in one dimension: as the temperature is reduced, the electronic
charge and spin tend to arrange themselves in an ordered fashion due to strong
correlations. The competition of the different interactions is responsible for
which broken-symmetry ground state is eventually realized in a specific
compound and which drives the system towards an insulating state.
Here we review the various ordering phenomena and how they can be identified
by optic and magnetic measurements. While the final results might look very
similar in the case of a charge density wave and a charge-ordered metal, for
instance, the physical cause is completely different. When density waves form,
a gap opens in the density of states at the Fermi energy due to nesting of the
one-dimension Fermi surface sheets. When a one-dimensional metal becomes a
charge-ordered Mott insulator, on the other hand, the short-range Coulomb
repulsion localizes the charge on the lattice sites and even causes certain
charge patterns.
We try to point out the similarities and conceptional differences of these
phenomena and give an example for each of them. Particular emphasis will be put
on collective phenomena which are inherently present as soon as ordering breaks
the symmetry of the system.Comment: Review article Naturwissenschaften 200
Electronic structure of the quasi-one-dimensional organic conductor TTF-TCNQ
We study the electronic structure of the quasi-one-dimensional organic
conductor TTF-TCNQ by means of density-functional band theory, Hubbard model
calculations, and angle-resolved photoelectron spectroscopy (ARPES). The
experimental spectra reveal significant quantitative and qualitative
discrepancies to band theory. We demonstrate that the dispersive behavior as
well as the temperature-dependence of the spectra can be consistently explained
by the finite-energy physics of the one-dimensional Hubbard model at metallic
doping. The model description can even be made quantitative, if one accounts
for an enhanced hopping integral at the surface, most likely caused by a
relaxation of the topmost molecular layer. Within this interpretation the ARPES
data provide spectroscopic evidence for the existence of spin-charge separation
on an energy scale of the conduction band width. The failure of the
one-dimensional Hubbard model for the {\it low-energy} spectral behavior is
attributed to interchain coupling and the additional effect of electron-phonon
interaction.Comment: 18 pages, 9 figure
The gauge invariant effective potential: equilibrium and non-equilibrium aspects
We propose a gauge invariant formulation of the effective potential in terms
of a gauge invariant order parameter, for the Abelian Higgs model. The one-loop
contribution at zero and finite temperature is computed explicitly, and the
leading terms in the high temperature expansion are obtained. The result is
contrasted to the effective potential obtained in several covariant
gauge-fixing schemes, and the gauge invariant quantities that can be reliably
extracted from these are identified. It is pointed out that the gauge invariant
effective potential in the one-loop approximation is complex for {\em all
values} of the order parameter between the maximum and the minimum of the tree
level potential, both at zero and non-zero temperature. The imaginary part is
related to long-wavelength instabilities towards phase separation. We study the
real-time dynamics of initial states in the spinodal region, and relate the
imaginary part of the effective potential to the growth rate of equal-time
gauge invariant correlation functions in these states. We conjecture that the
spinodal instabilities may play a role in non-equilibrium processes {\em
inside} the nucleating bubbles if the transition is first order.Comment: 27 pages revtex 3.0, no figures; one reference adde
One-Dimensional Fermi liquids
I attempt to give a pedagogical overview of the progress which has occurred
during the past decade in the description of one-dimensional correlated
fermions. Fermi liquid theory based on a quasi-particle picture, breaks down in
one dimension because of the Peierls divergence and because of charge-spin
separation. It is replaced by a Luttinger liquid whose elementary excitations
are collective charge and spin modes, based on the exactly solvable Luttinger
model. I review this model and various solutions with emphasis on bosonization
(and its equivalence to conformal field theory), and its physical properties.
The notion of a Luttinger liquid implies that all gapless 1D systems share
these properties at low energies.
Chapters 1 and 2 of the article contain an introduction and a discussion of
the breakdown of Fermi liquid theory. Chapter 3 describes in detail the
solution of the Luttinger model both by bosonization and by Green's functions
methods and summarizes the properties of the model, expressed thorugh
correlation functions. The relation to conformal field theory is discussed.
Chapter 4 of the article introduces the notion of a Luttinger liquid. It
describes in much detail the various mappings applied to realistic models of 1D
correlated fermions, onto the Luttinger model, as well as important corrections
to the Luttinger model properties discussed in Ch.3. Chapter 5 describes
situations where the Luttinger liquid is not a stable fixed point, and where
spin or charge gaps open in at least one channel. Chapter 6 discusses
multi-band and multichain problems, in particular the stability of a Luttinger
liquid with respect to interchain hopping. Ch. 7 gives a brief summary of
experimental efforts to uncover Luttinger liquid correlations in quasi-1D
materials.Comment: uuencoded Latex files and postscript figures, one Readme-file approx
160 pages + 13 figures; to be published by Reports on Progress in Physic
Children’s fascination with the Internet and parental monitoring of their activity online
Dane z wielu krajów dowodzą, że w ostatnich latach znacząco wzrósł odsetek dzieci i nastolatków które korzystają z Internetu nawet codziennie. Wpływ nowoczesnych technologii na rozwój dzieci rodzi wiele nadziei, ale też obaw i dylematów stawiając przed rodzicami nowe wyzwania. Celem niniejszego wystąpienia jest przegląd wybranych koncepcji teoretycznych i wyników badań własnych nad kontrolowaniem przez rodziców aktywności internetowej dzieci. W badaniach poszukiwano odpowiedzi na dwa podstawowe pytania: (1) czy istnieją statystycznie istotne różnice w zakresie monitoringu aktywności internetowej pomiędzy rodzicami dzieci rzadko oraz często korzystających z Internetu oraz (2) która ze zmiennych: poczucie bliskości w rodzinie oraz postawy rodziców wobec Internetu ma większy wpływ na poziom monitoringu aktywności internetowej dzieci (w grupie rodziców dzieci stosunkowo rzadko oraz codziennie korzystających z Internetu). W badaniach uczestniczyło 161 rodziców (20 ojców i 141 matek) dzieci w wieku od 7 do 12 lat. Wyniki badań wskazały, że rodzice, których dzieci korzystają z komputera rzadziej, silniej monitorują aktywność internetową dzieci oraz bardziej orientują się w celach, do jakich dzieci wykorzystują Internet, w porównaniu z rodzicami, których dzieci codzienne surfują w sieci. Ponadto, w grupie rodziców dzieci rzadko korzystających z Internetu najistotniejszym predyktorem monitoringu było poczucie bliskości w rodzinie, zaś w grupie rodziców dzieci często korzystających z Internetu najsilniejszymi predyktorami monitoringu były: percepcja korzyści z Internetu oraz percepcja Internetu jako zagrożenia (poczucie bliskości w rodzinie nie miało tu istotnego znaczenia).Recent data from many countries indicate that the percentage of children and teenagers using the Internet even on a daily basis has grown significantly. Influence of new technologies on children’s development raises a lot of hope but also causes parental concerns resulting in new challenges. The purpose of the presentation is to give an overview of selected theoretical concepts and own research results on parental controls over children’s Internet use. The answers were sought to two fundamental questions: (1) Are there any statistically significant differences in the control of children’s Internet use among parents whose children use it rarely (first group of parents) and those who use it frequently (second group of parents)? (2) Which of the two variables: the sense of family closeness or the parental attitude towards the Internet have stronger effect on the parental monitoring of children’s Internet use (in the groups of children using the Internet rarely vs. those who used it daily)? The participants were 161 parents (20 fathers and 141 mothers) of children aged 7-12 years. The results have shown that the first group controls the children’s Internet use more strongly than the second group and is aware of what their children use it for. The most essential predictors of the parental monitoring were: sense of family closeness (the first group) vs. parents’ Internet perception as a source of benefit and parents’ Internet perception as a threat or risk (the second group); the sense of family closeness was insignificant in the secod group
Free transverse vibrations of nanobeams with multiple cracks
A nonlocal model is formulated to study the size-dependent free transverse vibrations of nanobeams with arbitrary numbers of cracks. The effect of the crack is modeled by introducing discontinuities in the slope and transverse displacement at the cracked cross-section, proportional to the bending moment and the shear force transmitted through it. The local compliance of each crack is related to its stress intensity factors assuming that the crack tip stress field is undisturbed (non-interacting cracks).The kinematic field is defined based on the Bernoulli-Euler beam theory, and the small-scale size effect is taken into account by employing the constitutive equation of the stress-driven nonlocal theory of elasticity. In this manner, the curvature at each cross-section is defined as an integral convolution in terms of the bending moments at all the cross-sections and a kernel function which depends on a material characteristic length parameter. The integral form of the nonlocal constitutive equation is elaborated and converted into a differential equation subjected to a set of mathematically consistent boundary and continuity conditions at the nanobeam's ends and the cracked cross-sections. The equation of motion in each segment of the nanobeam between cracks is solved separately and the variationally consistent and constitutive boundary and continuity conditions are imposed to determine the natural frequencies. The model is applied to nanobeams with different boundary conditions and the natural frequencies and the mode shapes are presented at the presence of one to four cracks. The results of the model converge to the experimental results available in the literature for the local cracked beams and to the solutions of the intact nanobeams when the crack length goes to zero. The effects of the crack location, crack length, and nonlocality on the natural frequencies are investigated, also for the higher modes of vibrations. Novel findings including the amplification and shielding effects of the cracks on the natural frequencies are presented and discussed
Effects of multiple edge cracks, shear force, elastic foundation, and boundary conditions on bucking of small-scale pillars
The buckling instability of micro- and nanopillars can be an issue when designing intelligent miniaturized devices and characterizing composite materials reinforced with small-scale beam-like particles. Analytical modeling of the buckling of miniaturized pillars is especially important due to the difficulties in conducting experiments. Here, a well-posed stress-driven nonlocal model is developed, which allows the calculation of the critical loads and buckling configurations of the miniaturized pillars on an elastic foundation and with arbitrary numbers of edge cracks. The discontinuities in bending slopes and deflection at the damaged cross-sections due to the edge cracks are captured through the incorporation of both rotational and translational springs. A comprehensive analysis is conducted to investigate the instability of pillars containing a range of one to four cracks. This analysis reveals interesting effects regarding the influence of crack location, nonlocality, and elastic foundation on the initial and subsequent critical loads and associated buckling configurations. The main findings are: (i) the shielding and amplification effects related to a system of cracks become more significant as the dimensions of pillars reduce, (ii) the influence of the shear force at the damaged cross-section related to the translational spring must not be neglected when dealing with higher modes of buckling and long cracks, (iii) an elastic foundation decreases the effects of the cracks and size dependency on the buckling loads, and (iv) the effects of the edge cracks on the critical loads and buckling configurations of the miniaturized pillars are highly dependent on the boundary conditions