824 research outputs found
Direct Observation of Large Amplitude Spin Excitations Localized in a Spin-Transfer Nanocontact
We report the direct observation of large amplitude spin-excitations
localized in a spin-transfer nanocontact using scanning transmission x-ray
microscopy. Experiments were conducted using a nanocontact to an ultrathin
ferromagnetic multilayer with perpendicular magnetic anisotropy. Element
resolved x-ray magnetic circular dichroism images show an abrupt onset of spin
excitations at a threshold current that are localized beneath the nanocontact,
with average spin precession cone angles of 25{\deg} at the contact center. The
results strongly suggest that we have observed a localized magnetic soliton.Comment: 5 pages, 3 figure
X-Ray Detection of Transient Magnetic Moments Induced by a Spin Current in Cu
We have used a MHz lock-in x-ray spectro-microscopy technique to directly
detect changes of magnetic moments in Cu due to spin injection from an adjacent
Co layer. The elemental and chemical specificity of x-rays allows us to
distinguish two spin current induced effects. We detect the creation of
transient magnetic moments of on Cu atoms
within the bulk of the 28 nm thick Cu film due to spin-accumulation. The moment
value is compared to predictions by Mott's two current model. We also observe
that the hybridization induced existing magnetic moments on Cu interface atoms
are transiently increased by about 10% or .
This reveals the dominance of spin-torque alignment over Joule heat induced
disorder of the interfacial Cu moments during current flow
Safety and efficacy of topical tranexamic acid over intravenous tranexamic acid in reducing blood loss and transfusion rates in hip and knee arthroplasty
Background: Tranexamic acid (TXA) is increasingly used in orthopedic surgery to reduce blood loss. Hence the present study was undertaken to compare the efficacy of topical TXA and intravenous (IV) TXA in reducing blood loss and transfusion rate in primary total hip and total knee arthroplasty.Methods: Total of 31 cases undergoing either primary THA (23 cases) or TKA (8 cases) during a study period from June were enrolled. Outcome measures were drained output, transfusion rate, drop in haemoglobin (Hb) and blood loss measured by Nadler et al formula.Results: In THR group, 12 (52.17%) cases and in TKA group, 3 (37.5%) cases were managed using IV TXA whereas 11 (47.82%) and 5 (62.5%) cases were managed using topical TXA in THR and TKR group respectively. The mean drain output was greater among IV TKR group (261.66±129.60 ml) as compared to topical TKR group (210±129.49 ml). In THR drain output in IV group was 216±104.08 ml. In both the groups, mean blood loss was lower in cases where IV TXA was administered as compared to topical TXA, (p>0.05). The mean drop in Hb was greater after topical administration of TXA in both the groups as compared to IV administered TXA. In THR group, 9 (39.13%) patients required blood transfusion. In sickle cell disease patients, we found more blood loss and drain output as compared to non-sickle cell disease (SCD) patients.Conclusions: Both IV and topical TXA are clinically effective and safe in decreasing calculated blood loss, Hb drop after THA and TKA.
Direct observation and imaging of a spin-wave soliton with like symmetry
The prediction and realization of magnetic excitations driven by electrical
currents via the spin transfer torque effect, enables novel magnetic
nano-devices where spin-waves can be used to process and store information. The
functional control of such devices relies on understanding the properties of
non-linear spin-wave excitations. It has been demonstrated that spin waves can
show both an itinerant character, but also appear as localized solitons. So
far, it was assumed that localized solitons have essentially cylindrical,
like symmetry. Using a newly developed high-sensitivity time-resolved
magnetic x-ray microscopy, we instead observe the emergence of a novel
localized soliton excitation with a nodal line, i.e. with like symmetry.
Micromagnetic simulations identify the physical mechanism that controls the
transition from to like solitons. Our results suggest a potential new
pathway to design artificial atoms with tunable dynamical states using
nanoscale magnetic devices
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