1,038 research outputs found
Switching of +/-360deg domain wall states in a nanoring by an azimuthal Oersted field
We demonstrate magnetic switching between two domain wall vortex
states in cobalt nanorings, which are candidate magnetic states for robust and
low power MRAM devices. These domain wall (DW) or "twisted onion"
states can have clockwise or counterclockwise circulation, the two states for
data storage. Reliable switching between the states is necessary for any
realistic device. We accomplish this switching by applying a circular Oersted
field created by passing current through a metal atomic force microscope tip
placed at the center of the ring. After initializing in an onion state, we
rotate the DWs to one side of the ring by passing a current through the center,
and can switch between the two twisted states by reversing the current, causing
the DWs to split and meet again on the opposite side of the ring. A larger
current will annihilate the DWs and create a perfect vortex state in the rings.Comment: 5 pages, 5 figure
Undifferentiated Sarcoma of the Liver in the Adult
Os AA apresentam um caso clínico de sarcoma indiferenciado do fígado no adulto com metástases pulmonares, cardíacas e com recidiva local hepática. Salienta-se a contribuição dos exames complementares de diagnóstico, com especial relevo para a ecocardiografia no diagnóstico precoce de metástases intracardiacas. Não encontrámos qualquer outro caso descrito na literatura portuguesa
Sheath parameters for non-Debye plasmas: simulations and arc damage
This paper describes the surface environment of the dense plasma arcs that
damage rf accelerators, tokamaks and other high gradient structures. We
simulate the dense, non-ideal plasma sheath near a metallic surface using
Molecular Dynamics (MD) to evaluate sheaths in the non-Debye region for high
density, low temperature plasmas. We use direct two-component MD simulations
where the interactions between all electrons and ions are computed explicitly.
We find that the non-Debye sheath can be extrapolated from the Debye sheath
parameters with small corrections. We find that these parameters are roughly
consistent with previous PIC code estimates, pointing to densities in the range
. The high surface fields implied by these
results could produce field emission that would short the sheath and cause an
instability in the time evolution of the arc, and this mechanism could limit
the maximum density and surface field in the arc. These results also provide a
way of understanding how the "burn voltage" of an arc is generated, and the
relation between self sputtering and the burn voltage, while not well
understood, seems to be closely correlated. Using these results, and equating
surface tension and plasma pressure, it is possible to infer a range of plasma
densities and sheath potentials from SEM images of arc damage. We find that the
high density plasma these results imply and the level of plasma pressure they
would produce is consistent with arc damage on a scale 100 nm or less, in
examples where the liquid metal would cool before this structure would be lost.
We find that the sub-micron component of arc damage, the burn voltage, and
fluctuations in the visible light production of arcs may be the most direct
indicators of the parameters of the dense plasma arc, and the most useful
diagnostics of the mechanisms limiting gradients in accelerators.Comment: 8 pages, 16 figure
Minimal Gaugino Mediation
We propose Minimal Gaugino Mediation as the simplest known solution to the
supersymmetric flavor and CP problems. The framework predicts a very minimal
structure for the soft parameters at ultra-high energies: gaugino masses are
unified and non-vanishing whereas all other soft supersymmetry breaking
parameters vanish. We show that this boundary condition naturally arises from a
small extra dimension and present a complete model which includes a new
extra-dimensional solution to the mu problem. We briefly discuss the predicted
superpartner spectrum as a function of the two parameters of the model. The
commonly ignored renormalization group evolution above the GUT scale is crucial
to the viability of Minimal Gaugino Mediation but does not introduce new model
dependence.Comment: LaTeX, 16 pages, 4 figures, running of the bottom and tau Yukawas
included, plots revise
Magnetization reversal and exchange bias effects in hard/soft ferromagnetic bilayers with orthogonal anisotropies
The magnetization reversal processes are discussed for exchange-coupled ferromagnetic hard/soft bilayers made from Co[subscript 0.66]Cr[subscript 0.22]Pt[subscript 0.12] (10 and 20 nm)/Ni (from 0 to 40 nm) films with out-of-plane and in-plane magnetic easy axes respectively, based on room temperature hysteresis loops and first-order reversal curve analysis. On increasing the Ni layer thicknesses, the easy axis of the bilayer reorients from out-of-plane to in-plane. An exchange bias effect, consisting of a shift of the in-plane minor hysteresis loops along the field axis, was observed at room temperature after in-plane saturation. This effect was associated with specific ferromagnetic domain configurations experimentally determined by polarized neutron reflectivity. On the other hand, perpendicular exchange bias effect was revealed from the out-of-plane hysteresis loops and it was attributed to residual domains in the magnetically hard layer.National Science Foundation (U.S.)MIT-Spain/La Cambra de Barcelona Seed Fun
Excess degassing drives long-term volcanic unrest at Nevado del Ruiz
This study combines volcanic gas compositions, SO2 flux and satellite thermal data collected at Nevado del Ruiz between 2018 and 2021. We find the Nevado del Ruiz plume to have exhibited relatively steady, high CO2 compositions (avg. CO2/ST ratios of 5.4 ± 1.9) throughout. Our degassing models support that the CO2/ST ratio variability derives from volatile exsolution from andesitic magma stored in the 1–4 km depth range. Separate ascent of CO2-rich gas bubbles through shallow (< 1 km depth), viscous, conduit resident magma causes the observed excess degassing. We infer that degassing of ~ 974 mm3 of shallow (1–4 km) stored magma has sourced the elevated SO2 degassing recorded during 2018–2021 (average flux ~ 1548 t/d). Of this, only < 1 mm3 of magma have been erupted through dome extrusion, highlighting a large imbalance between erupted and degassed magma. Escalating deep CO2 gas flushing, combined with the disruption of passive degassing, through sudden accumulation and pressurization of bubbles due to lithostatic pressure, may accelerate volcanic unrest and eventually lead to a major eruption
Rocking ratchet induced by pure magnetic potentials with broken reflection symmetry
A ratchet effect (the rectification of an ac injected current) which is
purely magnetic in origin has been observed in a superconducting-magnetic
nanostructure hybrid. The hybrid consists of a superconducting Nb film in
contact with an array of nanoscale magnetic triangles, circular rings or
elliptical rings. The arrays were placed into well-defined remanent magnetic
states by application of different magnetic field cycles. The stray fields from
these remanent states provide a magnetic landscape which influences the motion
of superconducting vortices. We examined both randomly varying landscapes from
demagnetized samples, and ordered landscapes from samples at remanence after
saturation in which the magnetic rings form parallel onion states containing
two domain walls. The ratchet effect is absent if the rings are in the
demagnetized state or if the vortices propagate parallel to the magnetic
reflection symmetry axis (perpendicular to the magnetic domain walls) in the
ordered onion state. On the other hand, when the vortices move perpendicular to
the magnetic reflection symmetry axis in the ordered onion state (parallel to
the domain walls) a clear ratchet effect is observed. This behavior differs
qualitatively from that observed in samples containing arrays of triangular Ni
nanostructures, which show a ratchet of structural origin.Comment: 16 pages, 6 figures and 1 tabl
U(1) textures and Lepton Flavor Violation
U(1) family symmetries have led to successful predictions of the fermion mass
spectrum and the mixing angles of the hadronic sector. In the context of the
supersymmetric unified theories, they further imply a non-trivial mass
structure for the scalar partners, giving rise to new sources of flavor
violation. In the present work, lepton flavor non-conserving processes are
examined in the context of the minimal supersymmetric standard model augmented
by a U(1)-family symmetry. We calculate the mixing effects on the \mu-> e\gamma
and \tau -> \mu\gamma rare decays. All supersymmetric scalar masses involved in
the processes are determined at low energies using two loop renormalization
group analysis and threshold corrections. Further, various novel effects are
considered and found to have important impact on the branching ratios. Thus, a
rather interesting result is that when the see-saw mechanism is applied in the
(12 X 12)-sneutrino mass matrix, the mixing effects of the Dirac matrix in the
effective light sneutrino sector are canceled at first order. In this class of
models and for the case that soft term mixing is already present at the GUT
scale, tau -> \mu \gamma decays are mostly expected to arise at rates
significantly smaller than the current experimental limits. On the other hand,
the \mu \ra e \gamma rare decays impose important bounds on the model
parameters, particularly on the supersymmetric scalar mass spectrum. In the
absence of soft term mixing at high energies, the predicted branching ratios
for rare decays are, as expected, well below the experimental bounds.Comment: 24p, 10 figures, version to appear in Phys. Rev.
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