4,622 research outputs found
Updated Review of the Life and Reliability Models for HVDC Cables
This paper updates previous reviews of life and reliability models for HVDC cables. The update is motivated by the impressive R&D activities on HVDC cable systems in
the last years, with many projects at increasing levels of voltage and power; this makes the sound evaluation of life and reliability of HVDC cables crucial. Physical and
phenomenological life models proposed over the years for constant electrical and thermal stresses are reviewed first, including the relevant probabilistic framework and the effects of cable insulation volume enlargement. Then, more recent procedures for life and reliability estimation under time-varying electro-thermal stress are reported, focusing on thermal transients due to load cycles and voltage transients due to long Temporary Over-Voltages, Superimposed Switching Impulses and Voltage Polarity Reversals. Results of the application of such procedures are also presented, with a discussion on their limitations, and on open issues
Ground-State Properties of a One-Dimensional System of Hard Rods
A quantum Monte Carlo simulation of a system of hard rods in one dimension is
presented and discussed. The calculation is exact since the analytical form of
the wavefunction is known, and is in excellent agreement with predictions
obtained from asymptotic expansions valid at large distances. The analysis of
the static structure factor and the pair distribution function indicates that a
solid-like and a gas-like phases exist at high and low densities, respectively.
The one-body density matrix decays following a power-law at large distances and
produces a divergence in the low density momentum distribution at k=0 which can
be identified as a quasi-condensate.Comment: 4 pages, 4 figure
Single-particle vs. pair superfluidity in a bilayer system of dipolar bosons
We consider the ground state of a bilayer system of dipolar bosons, where
dipoles are oriented by an external field in the direction perpendicular to the
parallel planes. Quantum Monte Carlo methods are used to calculate the
ground-state energy, the one-body and two-body density matrix, and the
superfluid response as a function of the separation between layers. We find
that by decreasing the interlayer distance for fixed value of the strength of
the dipolar interaction, the system undergoes a quantum phase transition from a
single-particle to a pair superfluid. The single-particle superfluid is
characterized by a finite value of both the atomic condensate and the
super-counterfluid density. The pair superfluid phase is found to be stable
against formation of many-body cluster states and features a gap in the
spectrum of elementary excitations.Comment: 4 figure
Zero-temperature phase diagram of Yukawa bosons
We study the zero-temperature phase diagram of bosons interacting via
screened Coulomb (Yukawa) potential by means of the diffusion Monte Carlo
method. The Yukawa potential is used as a model interaction in the neutron
matter, dusty plasmas and charged colloids. As shown by D. S. Petrov et al.
[Phys. Rev. Lett. 99, 130407 (2007)], interactions between weakly bound
molecules of heavy and light fermionic atoms are described by an effective
Yukawa potential with a strength related to the heavy-light mass ratio M/m
which might lead to crystallization in a two-dimensional geometry if the mass
ratio of heavy-light fermions exceeds a certain critical value. In the present
work we do a thorough study of the quantum three-dimensional Yukawa system. For
strong interactions (equivalently, large mass ratios) the system experiences
several phase transitions as the density is increased, passing from gas to
solid and to gas phase again. Weakly interacting Yukawa particles do not
crystallize at any density. We find the minimal interaction strength at which
the crystallization happens. In terms of the two-component fermionic system,
this strength corresponds to a heavy-light mass ratio of M/m ~ 180, so that it
is impossible to realize the gas-crystal transition in a conventional bulk
system. For the Yukawa model of fermionic mixtures we also analyze the
possibility of building molecular systems with very large effective mass ratios
by confining the heavy component to a sufficiently deep optical lattice. We
show how the effective mass of the heavy component can be made arbitrarily
large by increasing the lattice depth, thus leading to a tunable effective mass
ratio that can be used to realize a molecular superlattice.Comment: added figure with finite-size dependence of the energy; comments and
references added; title change
Low-dimensional weakly interacting Bose gases: non-universal equations of state
The zero-temperature equation of state is analyzed in low-dimensional bosonic
systems. In the dilute regime the equation of state is universal in terms of
the gas parameter, i.e. it is the same for different potentials with the same
value of the s-wave scattering length. Series expansions of the universal
equation of state are reported for one- and two- dimensional systems. We
propose to use the concept of energy-dependent s-wave scattering length for
obtaining estimations of non-universal terms in the energy expansion. We test
this approach by making a comparison to exactly solvable one-dimensional
problems and find that the generated terms have the correct structure. The
applicability to two-dimensional systems is analyzed by comparing with results
of Monte Carlo simulations. The prediction for the non-universal behavior is
qualitatively correct and the densities, at which the deviations from the
universal equation of state become visible, are estimated properly. Finally,
the possibility of observing the non-universal terms in experiments with
trapped gases is also discussed.Comment: 11 pages, 4 figure
Genomic study, phytochemical characterization, and antiproliferative activity of two different genotypes of Jatropha curcas L. obtained by a breeding program
Jatropha curcas (Euphorbiaceaefamily) is a multipurpose plant with considerable potential in biodiesel production, and in cosmetic and medicinal uses. The part of J. curcas usually used is the oil obtained from its seeds, whereas the leaves generally represent the waste material. The aim of this study was to characterize the composition and to preliminary investigate the biological activity of J. curcas leaves obtained from plants by a breeding program. To describe genomic structure, molecular markers were applied. For biological study, two genotypes (JA and JB) that are genetically divergent were selected by cluster analysis. A phytochemical analysis was carried out to characterize the chemical composition of the extracts, which resulted rich in biologically active compounds, whereas toxic phorbol esters were absent. Biological assays showed an antiproliferative effect on the Buffalo normal rat liver cell line (BRL-3A), with genotype B being more potent than that of the counterpart (JA). The purified compounds isolated did not show antiproliferative activity, suggesting that the effect observed was due to the phytocomplex and should involve several secondary metabolites. This study highlights that a plant of the same genus and same species that has been cultivated in the same soil and climatic conditions can be characterized by a high variability. This is what makes research in pharmacognosya complex process
LOCAL ANAESTHETIC AVTIVITY OF ESSENTIAL OIL OF LAVANDULA ANGUSTIFOLIA
In this work we studied the local anaesthetic activity of the essential oil obtained from Lavandula angustifolia Mill., a medicinal plant traditionally used as an antispasmodic. We compared its activity to the essential oils obtained from two citrus fruits, Citrus reticulata Blanco and Citrus limon (L.) Burm. f., which have no medical uses. Biological tests were also performed on the major pure components of L. angustifolia Mill. essential oil: linalol and linalyl acetate as determined by GC and confirmed by GC-MS. Anaesthetic activity was evaluated in vivo in the rabbit conjunctival reflex test, and in vitro in a rat phrenic nerve-hemidiaphragm preparation. The essential oil of L. angustifolia, linalyl acetate and linalol (0.01-10 ÎĽg/ml) but not the oils of Citrus reticulata and Citrus limon were able to drastically reduce, in a dose-dependent manner, the electrically evoked contractions of rat phrenic-hemidiaphragm. In the rabbit conjunctival reflex test treatment with a solution of essential oil of L. angustifolia, as well as linalyl acetate and linalol (302500 ÎĽg/ml administered in the conjunctival sac) allow a dose-dependent increase in the number of stimuli necessary to provoke the reflex, thus confirming in vivo the local anaesthetic activity observed in vitro
Experimental Investigation of the Effect of Transient Overvoltages on XLPE-insulated HVDC Cables
HVDC cables are subject to several types of impulses superimposed on the rated DC voltage during their service lifetime. Temporary Overvoltages (TOVs) and Superimposed Switching impulses (SSIs) are considered some of the most challenging due to the relatively long impulse duration. This paper aims at investigating experimentally the effect of TOVs and SSIs on XLPE insulation for extruded HVDC cables. 0.15-mm-thick DC-XLPE specimens, aged by applying TOVs and SSIs, are characterized using dielectric analyzer and Fourier Transform InfraRed spectroscopy (FTIR) to detect the aging effects on the insulation. Results show an increase in the imaginary part of permittivity, ε", accompanied with the appearance of additional dipolar polarization losses peaks. The amplitude and frequency of the aforementioned peaks vary with the amplitude and the number of applied TOVs and SSIs. An increase in electrical conductivity is also noticed with aging. FTIR results show absorbance peaks in the aged specimens likely due to the intramolecular bonds rupture accompanied with the formation of aging products. In summary, SSIs and TOVs cause a noticeable reduction of insulating properties in XLPE specimens. The higher the peak of the transient, the greater the aging effect
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