445 research outputs found
Anharmonic Self-Energy of Phonons: Ab Initio Calculations and Neutron Spin Echo Measurements
We have calculated (ab initio) and measured (by spin-echo techniques) the
anharmonic self-energy of phonons at the X-point of the Brillouin zone for
isotopically pure germanium. The real part agrees with former, less accurate,
high temperature data obtained by inelastic neutron scattering on natural
germanium. For the imaginary part our results provide evidence that transverse
acoustic phonons at the X-point are very long lived at low temperatures, i.e.
their probability of decay approaches zero, as a consequence of an unusual
decay mechanism allowed by energy conservation.Comment: 8 pages, 2 figures, pdf fil
A purely geometric distance to the binary star Atlas, a member of the Pleiades
We present radial velocity and new interferometric measurements of the double
star Atlas, which permit, with the addition of published interferometric data,
to precisely derive the orbital parameters of the binary system and the masses
of the components. The derived semi-major axis, compared with its measured
angular size, allows to determine a distance to Atlas of 132+-4 pc in a purely
geometrical way. Under the assumption that the location of Atlas is
representative of the average distance of the cluster, we confirm the distance
value generally obtained through main sequence fitting, in contradiction with
the early Hipparcos result (118.3+-3.5 pc).Comment: 5 pages, 3 figures, accepted for publication in A&A Letter
Reduced dimensionality multiphysics model for efficient VCSEL optimization
The ICT scene is dominated by short-range intra-datacenter interconnects and networking, requiring high speed and stable operations at high temperatures. GaAs/AlGaAs vertical-cavity surface-emitting lasers (VCSELs) emitting at 850–980 nm have arisen as the main actors in this framework. Starting from our in-house 3D fully comprehensive VCSEL solver VENUS, in this work we present the possibility of downscaling the dimensionality of the simulation, ending up with a multiphysics 1D solver (D1ANA), which is shown to be capable of reproducing the experimental data very well. D1ANA is then extensively applied to optimize high-temperature operation, by modifying cavity detuning and distributed Bragg’s reflector lengths
Stabilization of tetragonal/cubic phase in Fe doped Zirconia grown by atomic layer deposition
Achieving high temperature ferromagnetism by doping transition metals thin
films is seen as a viable approach to integrate spin-based elements in
innovative spintronic devices. In this work we investigated the effect of Fe
doping on structural properties of ZrO2 grown by atomic layer deposition (ALD)
using Zr(TMHD)4 for Zr and Fe(TMHD)3 for Fe precursors and ozone as oxygen
source. The temperature during the growth process was fixed at 350{\deg}C. The
ALD process was tuned to obtain Fe doped ZrO2 films with uniform chemical
composition, as seen by time of flight secondary ion mass spectrometry. The
control of Fe content was effectively reached, by controlling the ALD precursor
pulse ratio, as checked by X-ray photoemission spectroscopy (XPS) and
spectroscopic ellipsometry. From XPS, Fe was found in Fe3+ chemical state,
which maximizes the magnetization per atom. We also found, by grazing incidence
X-ray diffraction, that the inclusion of Fe impurities in ZrO2 induces
amorphization in thin ZrO2 films, while stabilizes the high temperature
crystalline tetragonal/cubic phase after rapid thermal annealing at 600{\deg}C.Comment: 11 pages, 7 figures, 1 Tabl
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