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Beilstein J. Nanotechnol. 2020, 11, 651–661, doi:10.3762/bjnano.11.51
Figure 1: X-ray reciprocal space maps around the pseudo-cubic (103) Bragg reflection for the BTO/LSMO bilayer...
Figure 2: Sketch of lattice distortion of the LSMO crystal cell induced by the substrate: (a) compressive–str...
Figure 3: Normalized isothermal hysteresis loops at 300 K for LSMO films grown on (a) STO, (c) LSAT and (e) L...
Figure 4: Polar plots of the normalized remnant magnetization, at 300 K, for (a) LSMO (27 nm) layer (black st...
Figure 5: (a) Cross-section HAADF-STEM image for a BTO/LSMO bilayer grown on STO. Insets correspond to high-m...
Beilstein J. Nanotechnol. 2017, 8, 2106–2115, doi:10.3762/bjnano.8.210
Figure 1: SEM micrographs showing the dimensions of the grown cobalt nanospheres. Top view and front view of ...
Figure 2: Composition of the cobalt nanospheres, as measured by EDX, as a function of diameter.
Figure 3: SEM micrographs of the cobalt nanospheres grown on cantilever tips for STEM-EELS and electron holog...
Figure 4: STEM-EELS compositional analysis of the cobalt nanosphere with 110 nm diameter. (a) Reference image...
Figure 5: Electron holography of one cobalt nanosphere with a diameter of 110 nm. a) Electron hologram of the...
Figure 6: Cantilever magnetometry of a 500 nm diameter cobalt nanosphere. (a) Raw data of the cantilever freq...
Figure 7: Saturation magnetization of the cobalt nanospheres as a function of their diameter.
Beilstein J. Nanotechnol. 2015, 6, 1319–1331, doi:10.3762/bjnano.6.136
Figure 1: (a) A sketch of the FEBID process. (b) A SEM image of the nanowire with targeted width of 250 nm an...
Figure 2: MOKE results. (a) Average magnetic hysteresis loop of the sample with width/nominal thickness of 25...
Figure 3: Low-magnification TEM images of the iron nanowires with width of 250 nm and nominal thickness of (a...
Figure 4: Compositional analysis through EELS of the iron nanowires with nominal thickness of (a) 10 nm and (...
Figure 5: Sketch of the two-dimensional (y,z plane) geometrical shapes used in the micromagnetic simulation f...
Figure 6: Coercive field (HC) obtained from the simulations of iron nanowires with nominal width of 250 nm an...
Figure 7: Simulated magnetization reversal with five snapshots of the magnetization state in the nanowire wit...
Figure 8: Magnetization vector-color maps extracted from the simulations for 250 nm wide Fe nanowires with re...
Figure 9: Magnetization vector-color maps extracted from the simulations for 250 nm wide Fe nanowires with be...
Figure 10: Magnetization vector-color maps extracted from the simulations for 250 nm wide Fe nanowires with be...
Figure 11: Coercive field (HC) obtained from the simulations of nanowires as a function of tMax for the three ...