17,241 research outputs found
Magnetic excitations of perovskite rare-earth nickelates: RNiO
The perovskite nickelates RNiO (R: rare-earth) have been studied as
potential multiferroic compounds. A certain degree of charge disproportionation
in the Ni ions has been confirmed by high resolution synchrotron power
diffraction: instead of the nominal Ni valence, they can have the
mixed-valence state Ni and Ni, though agreement
has not been reached on the precise value of (e.g. for NdNiO,
and were reported). Also, the magnetic ground state
is not yet clear: collinear and non-collinear Ni-O magnetic structures have
been proposed to explain neutron diffraction and soft X-ray resonant
sccattering results in these compounds, and more recently a canted
antiferromagnetic spin arrangement was proposed on the basis of magnetic
susceptibility measurements. This scenario is reminiscent of the situation in
the half-doped manganites.
In order to gain insight into the ground state of these compounds, we studied
the magnetic excitations of some of the different phases proposed, using a
localized spin model for a simplified spin chain which could describe these
compounds. We first analize the stability of the collinear, orthogonal, and
intermediate phases in the classical case. We then explore the quantum ground
state indirectly, calculating the spin excitations obtained for each phase,
using the Holstein-Primakoff transformation and the linear spin-wave
approximation. For the collinear and orthogonal () phases, we
predict differences in the magnon spectrum which would allow to distinguish
between them in future inelastic neutron scattering experiments
Dust formation around AGB and SAGB stars: a trend with metallicity?
We calculate the dust formed around AGB and SAGB stars of metallicity Z=0.008
by following the evolution of models with masses in the range 1M<M<8M
throughthe thermal pulses phase, and assuming that dust forms via condensation
of molecules within a wind expanding isotropically from the stellar surface. We
find that, because of the strong Hot Bottom Burning (HBB) experienced, high
mass models produce silicates, whereas lower mass objects are predicted to be
surrounded by carbonaceous grains; the transition between the two regimes
occurs at a threshold mass of 3.5M. These fndings are consistent with the
results presented in a previous investigation, for Z=0.001. However, in the
present higher metallicity case, the production of silicates in the more
massive stars continues for the whole AGB phase, because the HBB experienced is
softer at Z=0.008 than at Z=0.001, thus the oxygen in the envelope, essential
for the formation of water molecules, is never consumed completely. The total
amount of dust formed for a given mass experiencing HBB increases with
metallicity, because of the higher abundance of silicon, and the softer HBB,
both factors favouring a higher rate of silicates production. This behaviour is
not found in low mass stars,because the carbon enrichment of the stellar
surface layers, due to repeated Third Drege Up episodes, is almost independent
of the metallicity. Regarding cosmic dust enrichment by intermediate mass
stars, we find that the cosmic yield at Z=0.008 is a factor 5 larger than at
Z=0.001. In the lower metallicity case carbon dust dominates after about 300
Myr, but at Z=0.008 the dust mass is dominated by silicates at all times,with a
prompt enrichment occurring after about 40 Myr, associated with the evolution
of stars with masses M =7.5 -8M.Comment: 14 pages, 10 figures, 2 Tables, accepted for publication in MNRA
Quantum magnons of the intermediate phase of half-doped manganite oxides
At half doping, the ground state of three-dimensional manganite perovskite
oxides like RCaMnO, where R is a trivalent ion such as La, Pr,
etc, is still unclear. Many experimental findings agree better with the
combined magnetic, charge, and orbital order characteristic of the
"intermediate phase", introduced by Efremov et al. in 2004 [Nature Mats. 3,
853]. This phase consists of spin dimers (thus incorporating aspects of the
Zener polaron phase (ZP) proposed in 2002 by Daoud-Aladine et al. [Phys. Rev.
Lett. 89, 097205]), though formed by a pair of parallel Mn spins of different
magnitude, in principle (thereby allowing for a degree of Mn charge
disproportionation: not necessarily as large as that of Mn-Mn in
Goodenough's original CE phase [Phys. Rev. 100, 564 (1955)]). In the
intermediate phase, consecutive spin dimers localed along the planar zig-zag
chains are oriented at a constant relative angle between them. Varying
Mn-charge disproportionation and , the intermediate phase should allow to
continuously interpolate between the two limiting cases of the CE phase and the
dimer phase denoted as "orthogonal intermediate phase". It is not easy
to find a microscopic model able to describe the phenomenological intermediate
phase adequately for the spin, charge, and orbital degrees of freedom
simultaneously. Here, we study the quantum spin excitations of a planar model
of interacting localized spins, which we found can stabilize the intermediate
phase classically. We compare the quantum magnons of the intermediate phase
with those of the CE and orthogonal phases, in the context of recent
experimental results.Comment: 5 pages, 8 figures Manuscript accepted 29 April 2013, by IEEE -
Transactions on Magnetic
Patent Valuation under Spatial Point Processes with Delayed and Decreasing Jump Intensity
This article is set within the real options approach applied to patent valuation. Such evaluation is based on the knowledge of the impact of some events on the underlying state, which is modeled in discrete time as a spatial point process, i.e. both size and time of the jumps can be treated as random variables. This assumption allows us to improve upon the current theory of patent valuation in some respects. In particular, the propagation of the jumps from the economic environment to the patent value is not restricted to be immediate, but can occur with a random delay and with varying intensity, depending on the time to maturity. These actual features lead to a more general formula for patent value that may give rise to a non-trivial difference not accounted for in the existing literature
Seismology of Procyon A: determination of mode frequencies, amplitudes, lifetimes, and granulation noise
The F5 IV-V star Procyon A (aCMi) was observed in January 2001 by means of
the high resolution spectrograph SARG operating with the TNG 3.5m Italian
telescope (Telescopio Nazionale Galileo) at Canary Islands, exploiting the
iodine cell technique. The time-series of about 950 spectra carried out during
6 observation nights and a preliminary data analysis were presented in Claudi
et al. 2005. These measurements showed a significant excess of power between
0.5 and 1.5 mHz, with ~ 1 m/s peak amplitude. Here we present a more detailed
analysis of the time-series, based on both radial velocity and line equivalent
width analyses. From the power spectrum we found a typical p-mode frequency
comb-like structure, identified with a good margin of certainty 11 frequencies
in the interval 0.5-1400 mHz of modes with l=0,1,2 and 7< n < 22, and
determined large and small frequency separations, Dn = 55.90 \pm 0.08 muHz and
dnu_02=7.1 \pm 1.3 muHz, respectively. The mean amplitude per mode (l=0,1) at
peak power results to be 0.45 \pm 0.07 m/s, twice larger than the solar one,
and the mode lifetime 2 \pm 0.4 d, that indicates a non-coherent, stochastic
source of mode excitation. Line equivalent width measurements do not show a
significant excess of power in the examined spectral region but allowed us to
infer an upper limit to the granulation noise.Comment: 10 pages, 15 figures, 4 tables. Accepted for publication in A&
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