6533b870fe1ef96bd12d0762
RESEARCH PRODUCT
Domain Wall Spin Structures in Mesoscopic Fe Rings probed by High Resolution SEMPA
Benjamin KrügerMathias KläuiPascal KrautscheidMaike LaufRobert M. Reevesubject
Mesoscopic physicsCondensed Matter - Materials ScienceMaterials scienceAcoustics and UltrasonicsMagnetic structureCondensed matter physicsMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciences02 engineering and technology021001 nanoscience & nanotechnologyCondensed Matter PhysicsPolarization (waves)01 natural sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsVortexMagnetizationTransverse planeMetastability0103 physical sciences010306 general physics0210 nano-technologySaturation (magnetic)description
We present a combined theoretical and experimental study of the energetic stability and accessibility of different domain wall spin configurations in mesoscopic magnetic iron rings. The evolution is investigated as a function of the width and thickness in a regime of relevance to devices, while Fe is chosen as a material due to its simple growth in combination with attractive magnetic properties including high saturation magnetization and low intrinsic anisotropy. Micromagnetic simulations are performed to predict the lowest energy states of the domain walls, which can be either the transverse or vortex wall spin structure, in good agreement with analytical models, with further simulations revealing the expected low temperature configurations observable on relaxation of the magnetic structure from saturation in an external field. In the latter case, following the domain wall nucleation process, transverse domain walls are found at larger widths and thicknesses than would be expected by just comparing the competing energy terms demonstrating the importance of metastability of the states. The simulations are compared to high spatial resolution experimental images of the magnetization using scanning electron microscopy with polarization analysis to provide a phase diagram of the various spin configurations. In addition to the vortex and simple symmetric transverse domain wall, a significant range of geometries are found to exhibit highly asymmetric transverse domain walls with properties distinct from the symmetric transverse wall. Simulations of the asymmetric walls reveal an evolution of the domain wall tilting angle with ring thickness which can be understood from the thickness dependencies of the contributing energy terms. Analysis of all the data reveals that in addition to the geometry, the influence of materials properties, defects and thermal activation all need to be taken into account in order to understand and reliably control the experimentally accessible states, as needed for devices.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-01-01 |