2019
DOI: 10.1038/s41598-019-54356-y
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X-ray magnetic linear dichroism as a probe for non-collinear magnetic state in ferrimagnetic single layer exchange bias systems

Abstract: Ferrimagnetic alloys are extensively studied for their unique magnetic properties leading to possible applications in perpendicular magnetic recording, due to their deterministic ultrafast switching and heat assisted magnetic recording capabilities. On a prototype ferrimagnetic alloy we demonstrate fascinating properties that occur close to a critical temperature where the magnetization is vanishing, just as in an antiferromagnet. From the X-ray magnetic circular dichroism measurements, an anomalous ‘wing shap… Show more

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Cited by 17 publications
(19 citation statements)
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“…2g and h, respectively. This is in agreement with previous results showing that GST transforms from an amorphous phase to a face-centered cubic lattice at 155°C [32][33][34] . The 160 nm GST film thickness was measured as 160, 152, and 149 nm at 25, 240, and 400°C, respectively, and similarly the 40 nm GST film thickness as 38.7, 36.9, and 33.7 nm at 25, 240, and 400°C.…”
Section: Resultssupporting
confidence: 93%
“…2g and h, respectively. This is in agreement with previous results showing that GST transforms from an amorphous phase to a face-centered cubic lattice at 155°C [32][33][34] . The 160 nm GST film thickness was measured as 160, 152, and 149 nm at 25, 240, and 400°C, respectively, and similarly the 40 nm GST film thickness as 38.7, 36.9, and 33.7 nm at 25, 240, and 400°C.…”
Section: Resultssupporting
confidence: 93%
“…The same table gives the compensation temperatures, T Comp , of the alloys and their coercive fields at 2 K and RT. T Comp temperature was smaller in sample DCM (90 K) than in sample DCC (120 K), in agreement with their different RE concentration, and with the expected by comparing with the reported by others in DyCo alloys of similar concentrations [5,20], assuming a linear relationship between T Comp and the atomic concentration of the alloy [18]. The higher cobalt concentration in sample DCM causes a marked lower magnetic remanence at 10 K than in sample DCC.…”
Section: A Magnetometrysupporting
confidence: 90%
“…X ray reflectometry shows rougher surfaces in DCM than in DCC thin films, suggesting that the larger H C of the DCM thin film is probably caused by its higher density of domain wall pinning defects. The coercive fields of both samples were notoriously higher than the reported in DyCo 4 by others [5,20], with H C values lower than 1 T at a similar decrement (∆T=150 K) in temperature from their T Comp (250 K). This might account for a higher PMA energy and/or domain wall pinning defects density in our samples.…”
Section: A Magnetometrymentioning
confidence: 46%
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“…The exchange bias effect is that the hysteresis loop of the ferromagnetic(FM) layer deviates from the magnetic field direction after the system is cooled from the Neel temperature (T Neel ) of anti-ferromagnetic(AFM). The systems can consist of permanent magnetic/soft magnetic [1], permanent magnetic/anti-ferromagnetic [2], (FM)/(AFM) [3], ferrimagnetic(FIM)/(AFM) [4] film system [5], core-shell system [6], alloy system [7], etc. In 1956, Meiklejohn and Bean [8] discovered the exchange bias effect, which was due to the spin interaction at the interface of Co nanoparticles covered by CoO, and the hysteresis loop moved along the magnetic field axis after the applied magnetic field cooled.…”
Section: Introductionmentioning
confidence: 99%