We
investigated spin-to-charge conversion in sputtered Bi43Se57/Co20Fe60B20 heterostructures
with in-plane magnetization at room temperature. High spin-to-charge
conversion voltage signals have been observed at room temperature.
The transmission electron microscope images show that the sputtered
bismuth selenide thin films are nanogranular in structure. The spin-pumping
voltage decreases with an increase in the size of the grains. The
inverse Edelstein effect length (λIEE) is estimated
to be as large as 0.32 nm. The large λIEE is due
to the spin-momentum locking and is further enhanced by quantum confinement
in the nanosized grains of the sputtered bismuth selenide films. We
also investigated the effect on spin-pumping voltage due to the insertion
of layers of MgO and Ag. The MgO insertion layer has almost completely
suppressed the spin-pumping voltage, whereas the Ag insertion layer
has enhanced the λIEE by 43%.
The greatest challenge for lithium−sulfur (Li−S) batteries application is the development of cathode hosts to address the low conductivity, huge volume change, and shuttling effect of sulfur or lithium polysulfides (LiPs). Herein, we demonstrate a composite host to circumvent these problems by confining sub-nanometric manganous oxide clusters (MOCs) in nitrogen doped mesoporous carbon nanosheets. The atomic structure of MOCs is well-characterized and optimized via the extended X-ray absorption fine structure analysis and density functional theory (DFT) calculations. Benefiting from the unique design, the assembled Li−S battery displays remarkable electrochemical performances including a high reversible capacity (990 mAh g −1 after 100 cycles at 0.2 A g −1 ) and a superior cycle life (60% retention over 250 cycles at 2 A g −1 ). Both the experimental results and DFT calculations demonstrate that the well-dispersed MOCs could significantly promote the chemisorption of LiPs, thus greatly improving the capacity and rate performance.
Superparamagnetic iron oxide nanoparticles (SPIONs) have been extensively used as bioimaging contrast agents, heating sources for tumor therapy, and carriers for controlled drug delivery and release to target organs and tissues. These applications require elaborate tuning of the physical and magnetic properties of the SPIONs. The authors present here a search-coil-based method to characterize these properties. The nonlinear magnetic response of SPIONs to alternating current magnetic fields induces harmonic signals that contain information of these nanoparticles. By analyzing the phase lag and harmonic ratios in the SPIONs, the authors can predict the saturation magnetization, the average hydrodynamic size, the dominating relaxation processes of SPIONs, and the distinction between single- and multicore particles. The numerical simulations reveal that the harmonic ratios are inversely proportional to saturation magnetizations and core diameters of SPIONs, and that the phase lag is dependent on the hydrodynamic volumes of SPIONs, which corroborate the experimental results. Herein, the authors stress the feasibility of using search coils as a method to characterize physical and magnetic properties of SPIONs, which may be applied as building blocks in nanoparticle characterization devices.
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