326 research outputs found
Receiver Function Analysis at Stromboli Volcano (Italy)
This study focuses on constraining the crust and upper mantle discontinuities at Stromboli
volcano by applying the receiver function (RF) analysis. This technique utilizes
the waveforms of P-SV conversions generated by discontinuities to infer the structure
beneath the seismic stations. RFs have been obtained by deconvolving the vertical
component of teleseismic P-wave records from the corresponding rotate horizontal
components applying the Multi-Taper Spectral Correlation technique. For this study
the seismograms of about 125 teleseismic earthquakes (M greater than 6.0), recorded
between 2004 and 2006 at 13 broad-band seismic stations deployed by the INGV, have
been considered. A preliminar characterization of the structure beneath the stations has
been inferred from the stacking of teleseismic Ps converted waves and multiply converted
waves at the seismic interface. The analysis, at frequency of 1 and 2 Hz, show
a horizontal seismic discontinuity at an average depth of about 17 km and a Vp/Vs
ratio lower than 1.73. This discontinuity explains the positive pulses about 1.9 s and
7.5 s after the direct P arrival. These pulses can be interpreted as Ps and PpPs converted
phases, respectively. The depth of this discontinuity is in agreement with the
Moho-depth obtained in independent studies
Adiabatic dynamics of a quantum critical system coupled to an environment: Scaling and kinetic equation approaches
We study the dynamics of open quantum many-body systems driven across a
critical point by quenching an Hamiltonian parameter at a certain velocity.
General scaling laws are derived for the density of excitations and energy
produced during the quench as a function of quench velocity and bath
temperature. The scaling laws and their regimes of validity are verified for
the XY spin chain locally coupled to bosonic baths. A detailed derivation and
analysis of the kinetic equation of the problem is presented.Comment: 15 pages, 13 figure
Fault plane orientations of microearthquakes at Mt. Etna from theinversion of P-wave rise times
A crucial point in the analysis of tectonic earthquakes occurring in a volcanic area is the inference of the
orientation of the structures along which the ruptures occur. These structures represent zones of weakness
which could favor the migration of melt toward the surface and the assessment of their geometry is a
fundamental step toward efficient evaluation of volcanic risk. We analyzed a high-quality dataset of 171 lowmagnitude,
tectonic earthquakes that occurred at Mt. Etna during the 2002–2003 eruption. We applied a
recently developed technique aimed at inferring the source parameters (source size, dip and strike fault) and
the intrinsic quality factor Qp of P waves from the inversion of rise times. The technique is based on
numerically calibrated relationships among the rise time of first P waves and the source parameters for a
circular crack rupturing at a constant velocity. For the most of the events the directivity source effect did not
allow us to constrain the fault plane orientation. For a subset of 45 events with well constrained focal
mechanisms we were able to constrain the “true” fault plane orientation. The level of resolution of the fault
planes was assessed through a non linear analysis based on the random deviates technique. The significance
of the retrieved fault plane solutions and the fit of the assumed source model to data were assessed through
a χ-square test. Most of the retrieved fault plane solutions agree with the geometrical trend of known
surface faults. The inferred source parameters and Qp are in agreement with the results of previous studie
Near-field spectroscopy of phase segregation in white-light-emitting blends based on low-mass molecules
We report on the direct observation of phase segregation occurring in thin-film blends of a thiophene monomer and an ammino compound, used in the fabrication of organic white-light-emitting diodes. In the homogeneous and uniform regions of the films, the interaction between the two molecular components gives rise to exciplex states responsible for a broad redshifted photoluminescence emission band, which disappears in the film zones where segregation occurs. This effect has been observed with submicrometer spatial resolution by means of local spectroscopic measurements performed in a scanning near-field optical microscope
Fault plane orientation of microearthquakes at Mt. etna from the inversion of P-wave rise times
crucial point in the analysis of tectonic earthquakes occurring in a volcanic area is the inference of the orientation of the structures along which the ruptures occur. These structures represent zones of weakness which could favor the migration of melt toward the surface and the assessment of their geometry is a fundamental step toward efficient evaluation of volcanic risk. We analyzed a high-quality dataset of 171 low-magnitude, tectonic earthquakes occurred at Mt. Etna during the 2002-2003 eruption. We applied a recently developed technique aimed at inferring the source parameters (source size, dip and strike fault) and the intrinsic quality factor Qp of P waves from the inversion of rise times. The technique is based on numerically calibrated relationships among the rise time of first P waves and the source parameters for a circular crack rupturing at a constant velocity. For the most of the events the directivity source effect did not allow us to constrain the fault plane orientation. For a subset of 45 events with well constrained focal mechanisms we were able to constrain the “true” fault plane orientation. The level of resolution of the fault planes was assessed through a non linear analysis based on the random deviates technique. The significance of the retrieved fault plane solutions and the fit of the assumed source model to data was assessed through a χ-square test. Most of the retrieved fault plane solutions agree with the geometrical trend of known surface faults. The inferred source parameters and Qp are in agreement with the results of previous studies
Bose-Einstein condensation and entanglement in magnetic systems
We present a study of magnetic field induced quantum phase transitions in
insulating systems. A generalized scaling theory is used to obtain the
temperature dependence of several physical quantities along the quantum
critical trajectory (, ) where is a longitudinal external
magnetic field and the critical value at which the transition occurs.
We consider transitions from a spin liquid at a critical field and
from a fully polarized paramagnet, at , into phases with long range
order in the transverse components. The transitions at and
can be viewed as Bose-Einstein condensations of magnons which however belong to
different universality classes since they have different values of the dynamic
critical exponent . Finally, we use that the magnetic susceptibility is an
entanglement witness to discuss how this type of correlation sets in as the
system approaches the quantum critical point along the critical trajectory,
, .Comment: 7 pages, 1 Table; accepted version; changes in text and new
reference
Linear magnetoresistance in commercial n-type silicon due to inhomogeneous doping
Free electron theory tells us that resistivity is independent of magnetic
field. In fact, most observations match the semiclassical prediction of a
magnetoresistance that is quadratic at low fields before saturating. However, a
non-saturating linear magnetoresistance has been observed in exotic
semiconductors such as silver chalcogenides, lightly-doped InSb, N-doped InAs,
MnAs-GaAs composites, PrFeAsO, and epitaxial graphene. Here we report the
observation of a large linear magnetoresistance in the ohmic regime in
commonplace commercial n-type silicon wafer. It is well-described by a
classical model of spatially fluctuating donor densities, and may be amplified
by altering the aspect ratio of the sample to enhance current-jetting:
increasing the width tenfold increased the magnetoresistance at 8 T from 445 %
to 4707 % at 35 K. This physical picture may well offer insights into the large
magnetoresistances recently observed in n-type and p-type Si in the non-ohmic
regime.Comment: submitted to Nature Material
Indoor and soil radon measurements in the Hyblean Foreland (South-East Sicily)
Indoor radon behavior in two sites of SE Sicily was studied as a function of the soil radon concentration. The
chosen locations were Ragusa and Modica towns, placed in the Hyblean Plateau (northern margin of the African
Plate). Soil samples were analysed by gamma spectrometry to determine the amount of radionuclides. Indoor air
and soil gas radon measurements were simultaneously performed in both sites using active detectors. Radon in
soil was measured one meter deep. A positive correlation was obtained between indoor radon concentration and
the soil gas concentration
Toward Forecasting Volcanic Eruptions using Seismic Noise
During inter-eruption periods, magma pressurization yields subtle changes of
the elastic properties of volcanic edifices. We use the reproducibility
properties of the ambient seismic noise recorded on the Piton de la Fournaise
volcano to measure relative seismic velocity variations of less than 0.1 % with
a temporal resolution of one day. Our results show that five studied volcanic
eruptions were preceded by clearly detectable seismic velocity decreases within
the zone of magma injection. These precursors reflect the edifice dilatation
induced by magma pressurization and can be useful indicators to improve the
forecasting of volcanic eruptions.Comment: Supplementary information:
http://www-lgit.obs.ujf-grenoble.fr/~fbrengui/brenguier_SI.pdf Supplementary
video:
http://www-lgit.obs.ujf-grenoble.fr/~fbrengui/brenguierMovieVolcano.av
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