45 research outputs found
Structure and morphology of epitaxially grown Fe3O4/NiO bilayers on MgO(001)
Crystalline Fe3O4/NiO bilayers were grown on MgO(001) substrates using
reactive molecular beam epitaxy to investigate their structural properties and
their morphology. The film thickness either of the Fe3O4 film or of the NiO
film has been varied to shed light on the relaxation of the bilayer system. The
surface properties as studied by x-ray photo electron spectroscopy and low
energy electron diffraction show clear evidence of stoichiometric well-ordered
film surfaces. Based on the kinematic approach x-ray diffraction experiments
were completely analyzed. As a result the NiO films grow pseudomorphic in the
investigated thickness range (up to 34nm) while the Fe3O4 films relax
continuously up to the thickness of 50nm. Although all diffraction data show
well developed Laue fringes pointing to oxide films of very homogeneous
thickness, the Fe3O4-NiO interface roughens continuously up to 1nm
root-mean-square roughness with increasing NiO film thickness while the Fe3O4
surface is very smooth independent on the Fe3O4 film thickness. Finally, the
Fe3O4-NiO interface spacing is similar to the interlayer spacing of the oxide
films while the NiO-MgO interface is expanded.Comment: 20 pages including 12 figure
Effects of environmental parameters on chytrid infection prevalence of four marine diatoms : a laboratory case study
Acknowledgements: The Icelandic Research Fund (grant reference 141423-051) is gratefully acknowledged for its support to BS.Peer reviewedPublisher PD
Free-sustaining three-dimensional S235 steel-based porous electrocatalyst for highly efficient and durable oxygen evolution
A novel oxygen evolution reaction (OER) catalyst (3D S235-P steel) based on steel S235 substrate has been successfully prepared via a facile one-step surface modification. The standard Carbon Manganese steel was phosphorizated superficially leading to the formation of a unique 3D interconnected nanoporous surface with high specific area which facilitates the electrocatalytically initiated oxygen evolution reaction. The prepared 3D S235-P steel exhibits enhanced electrocatalytic OER activities in alkaline regime confirmed by a low overpotential (η=326 mV at j=10 mA cm-2) and a small Tafel slope of 68.7 mV dec-1. Moreover, the catalyst was found to be stable under long-term usage conditions functioning as oxygen evolving electrode at pH 13 as evidenced by the sufficient charge to oxygen conversion rate (Faradaic efficiency: 82.11% and 88.34% at 10 mA cm-2 and 5 mA cm-2, respectively). In addition, it turned out that the chosen surface modification renders steel S235 into an OER electrocatalyst sufficiently and stable to work in neutral pH condition. Our investigation revealed that the high catalytic activities are likely to stem from the generated Fe/(Mn) hydroxide/oxo-hydroxides generated during the OER process. The phosphorization treatment is therefore not only an efficient way to optimize the electrocatalytic performance of standard Carbon-Manganese steel, but also enables for the development of low cost and abundant steels in the field of energy conversion
Impact of Strain and Morphology on Magnetic Properties of Fe3O4/NiO Bilayers Grown on Nb:SrTiO3(001) and MgO(001)
Kuschel O, Pathé N, Schemme T, et al. Impact of Strain and Morphology on Magnetic Properties of Fe3O4/NiO Bilayers Grown on Nb:SrTiO3(001) and MgO(001). Materials. 2018;11(7): 1122.We present a comparative study of the morphology and structural as well as magnetic properties of crystalline Fe3O4/NiO bilayers grown on both MgO(001) and SrTiO3(001) substrates by reactive molecular beam epitaxy. These structures were investigated by means of X-ray photoelectron spectroscopy, low-energy electron diffraction, X-ray reflectivity and diffraction, as well as vibrating sample magnetometry. While the lattice mismatch of NiO grown on MgO(001) was only 0.8%, it was exposed to a lateral lattice mismatch of -6.9% if grown on SrTiO3. In the case of Fe3O4, the misfit strain on MgO(001) and SrTiO3(001) amounted to 0.3% and -7.5%, respectively. To clarify the relaxation process of the bilayer system, the film thicknesses of the magnetite and nickel oxide films were varied between 5 and 20 nm. While NiO films were well ordered on both substrates, Fe3O4 films grown on NiO/SrTiO3 exhibited a higher surface roughness as well as lower structural ordering compared to films grown on NiO/MgO. Further, NiO films grew pseudomorphic in the investigated thickness range on MgO substrates without any indication of relaxation, whereas on SrTiO3 the NiO films showed strong strain relaxation. Fe3O4 films also exhibited strong relaxation, even for films of 5nm thickness on both NiO/MgO and NiO/SrTiO3. The magnetite layers on both substrates showed a fourfold magnetic in-plane anisotropy with magnetic easy axes pointing in directions. The coercive field was strongly enhanced for magnetite grown on NiO/SrTiO3 due to the higher density of structural defects, compared to magnetite grown on NiO/MgO
Sign change in the tunnel magnetoresistance of Fe3O4/MgO/Co-Fe-B magnetic tunnel junctions depending on the annealing temperature and the interface treatment
Magnetite (Fe3O4) is an eligible candidate for magnetic tunnel junctions
(MTJs) since it shows a high spin polarization at the Fermi level as well as a
high Curie temperature of 585{\deg}C. In this study, Fe3O4/MgO/Co-Fe-B MTJs
were manufactured. A sign change in the TMR is observed after annealing the
MTJs at temperatures between 200{\deg}C and 280{\deg}C. Our findings suggest an
Mg interdiffusion from the MgO barrier into the Fe3O4 as the reason for the
change of the TMR. Additionally, different treatments of the magnetite
interface (argon bombardment, annealing at 200{\deg}C in oxygen atmosphere)
during the preparation of the MTJs have been studied regarding their effect on
the performance of the MTJs. A maximum TMR of up to -12% could be observed
using both argon bombardment and annealing in oxygen atmosphere, despite
exposing the magnetite surface to atmospheric conditions before the deposition
of the MgO barrier.Comment: 5 pages, 5 figures, 2 table
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Tuning the properties of magnetic thin films by interaction with periodic nanostructures
The most important limitation for a significant increase of the areal storage density in magnetic recording is the superparamagnetic effect. Below a critical grain size of the used CoCrPt exchange-decoupled granular films the information cannot be stored for a reasonable time (typically ten years) due to thermal fluctuations arbitrary flipping of the magnetization direction. An alternative approach that may provide higher storage densities is the use of so-called percolated media, in which defect structures are imprinted in an exchange-coupled magnetic film. Such percolated magnetic films are investigated in the present work. We employ preparation routes that are based on (i) self-assembly of Au nanoparticles and (ii) homogeneous size-reduction of self-assembled polystyrene particles. On such non-close-packed nanostructures thin Fe films or Co/Pt multilayers are grown with in-plane and out-of-plane easy axis of magnetization. The impact of the particles on the magnetic switching behavior is measured by both integral magnetometry and magnetic microscopy techniques. We observe enhanced coercive fields while the switching field distribution is broadened compared to thin-film reference samples. It appears possible to tailor the magnetic domain sizes down to the width of an unperturbed domain wall in a continuous film, and moreover, we observe pinning and nucleation at or close to the imprinted defect structures
Heptanuclear [FeIII6CrIII]3+ Complexes Experimentally Studied by Means of Magnetometry, X-ray Diffraction, XAS, XMCD and Spin-Polarized Electron Spectroscopy in Cross-Comparison with [MnIII6CrIII]3+ Single-Molecule Magnets
Dohmeier N, Helmstedt A, MĂŒller N, et al. Heptanuclear [FeIII6CrIII]3+ Complexes Experimentally Studied by Means of Magnetometry, X-ray Diffraction, XAS, XMCD and Spin-Polarized Electron Spectroscopy in Cross-Comparison with [MnIII6CrIII]3+ Single-Molecule Magnets. Magnochemistry. 2016;2(1): 5
X20CoCrWMo10-9//Co3O4: a Metal-Ceramic Composite with Unique Efficiency Values for Water-Splitting in Neutral Regime
Water splitting allows the storage of solar energy into chemical bonds
(H2+O2) and will help to implement the urgently needed replacement of limited
available fossil fuels. Particularly in neutral environment electrochemically
initiated water splitting suffers from low efficiency due to high
overpotentials caused by the anode. Electro-activation of X20CoCrWMo10-9, a
Co-based tool steel resulted in a new composite material
(X20CoCrWMo10-9//Co3O4) that catalyzes the anode half-cell reaction of water
electrolysis with a so far unequalled effectiveness. The current density
achieved with this new anode in pH 7 corrected 0.1 M phosphate buffer is over a
wide range of overpotentials around 10 times higher compared to recently
developed, up-to-date electrocatalysts and represents the benchmark performance
advanced catalysts show in regimes that support water splitting significantly
better than pH 7 medium. X20CoCrWMo10-9//Co3O4 exhibited electrocatalytic
properties not only at pH 7, but also at pH 13, which is much superior to the
ones of IrO2-RuO2, single-phase Co3O4- or Fe/Ni- based catalysts. Both XPS and
FT-IR experiments unmasked Co3O4 as the dominating compound on the surface of
the X20CoCrWMo10-9//Co3O4 composite. Upon a comprehensive dual beam FIB-SEM
(focused ion beam-scanning electron microscopy) study we could show that the
new composite does not exhibit a classical substrate-layer structure due to the
intrinsic formation of the Co-enriched outer zone. This structural
particularity is basically responsible for the outstanding electrocatalytic OER
performance
Sign change in the tunnel magnetoresistance of Fe3O4/MgO/Co-Fe-B magnetic tunnel junctions depending on the annealing temperature and the interface treatment
Marnitz L, Rott K, Niehörster S, et al. Sign change in the tunnel magnetoresistance of Fe3O4/MgO/Co-Fe-B magnetic tunnel junctions depending on the annealing temperature and the interface treatment. AIP Advances. 2015;5(4): 047103.Magnetite (Fe3O4) is an eligible candidate for magnetic tunnel junctions (MTJs) since it shows a high spin polarization at the Fermi level as well as a high Curie temperature of 585°C. In this study, Fe3O4/MgO/Co-Fe-B MTJs were manufactured. A sign change in the TMR is observed after annealing the MTJs at temperatures between 200°C and 280°C. Our findings suggest an Mg interdiffusion from the MgO barrier into the Fe3O4 as the reason for the change of the TMR. Additionally, different treatments of the magnetite interface (argon bombardment, annealing at 200°C in oxygen atmosphere) during the preparation of the MTJs have been studied regarding their effect on the performance of the MTJs. A maximum TMR of up to -12% could be observed using both argon bombardment and annealing in oxygen atmosphere, despite exposing the magnetite surface to atmospheric conditions before the deposition of the MgO barrier