Ferrimagnetic Tb–Fe Alloy Thin Films: Composition and Thickness Dependence of Magnetic Properties and All-Optical Switching

Hebler, Birgit; Hassdenteufel, Alexander; Reinhardt, Peter; Karl, H.; Albrecht, Manfred

doi:10.3389/fmats.2016.00008

Cited by 93 publications

(78 citation statements)

References 65 publications

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“…1(a). As expected, both layers do not show a compensation temperature for these compositions and stay either Tb or Fe dominant [32,33]. We also determined the uniaxial magnetic anisotropy constant K U of both layers as a function of temperature using the expression…”

Section: Resultsmentioning

confidence: 60%

“…Growth-induced variations in the short range order, resulting in a redistribution of the orientation of the Tb magnetic moments, are responsible for the thickness dependence, as discussed in detail in Ref. [32].…”

Section: Resultsmentioning

confidence: 96%

“…Furthermore, the interfacial layer can only act as a pinning layer if its coercivity gets larger than the available field range (up to ±80 kOe) at a certain temperature. Apparently, this perquisite depends strongly on the thickness of the FI layers, which is typically associated with a strong variation of the magnetic properties present in this thickness range [32]. Please note that, also, the order of the layer stack plays an important role.…”

Section: Resultsmentioning

confidence: 99%

“…In addition, the presence of a compensation point is not required for the occurrence of the EB effect. It is assumed that this interfacial region is formed during the growth process due to interface mixing and re-sputtering effects, where for certain Tb-Fe compositions, hard magnetic properties can be achieved [32]. An example of a 20-nm-thick Tb 22 Fe 78 single layer is included in Fig.…”

Section: Resultsmentioning

confidence: 99%

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Double exchange bias in ferrimagnetic heterostructures

et al. 2017

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We report on the magnetic reversal characteristics of exchange coupled ferrimagnetic (FI) Tb 19 Fe 81 /Tb 36 Fe 64 heterostructures. Both layers are amorphous and exhibit strong perpendicular magnetic anisotropy. The investigated heterostructures consist of a Tb-dominated and a Fe-dominated FI layer. Thus, in the magnetic ground state the net moments of the individual layers are oppositely aligned due to antiferromagnetic coupling of Fe and Tb moments. By cooling the system below 160 K, a large positive and negative exchange bias (EB) effect appears for the Tb-and Fe-dominated layers, respectively. The biasing depends only on the initial magnetization state and is neither affected by a cooling field nor by loop cycling. The phenomenon can be explained by the presence of a hard magnetic Fe-dominated interfacial layer, which forms during the sputter deposition process due to interface mixing and resputtering effects. This interfacial layer acts as a pinning layer below a certain temperature, where its coercivity increases to values larger than the accessible magnetic field range. This assumption is further supported by introducing a 0.9-nm-thick Ru spacer layer, which causes the EB effect to vanish. The EB effect was further investigated for a sample series, where the thickness ratio of the two Tb-Fe layers was varied, while keeping the total thickness of the bilayers constant. Only samples where the individual layers are sufficiently thick reveal double shifted loops, indicating the high sensitivity of the observed bias effect with respect to the magnetic properties of the individual layers and their interfacial area.

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Section: Resultsmentioning

confidence: 60%

Section: Resultsmentioning

confidence: 96%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Double exchange bias in ferrimagnetic heterostructures

et al. 2017

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“…All-optical writing was demonstrated for ferrimagnetic rare-earth transition metal alloy films GdCoFe or TbCoFe around the compensation temperature of the rare-earth and transition metal moments, Figure 6(a) shows single shot switching with two helicities. 73 It was found that the situation is quite complex, 78,79 and it became evident that the demagnetization (memory loss of the spin system) together with some symmetry-breaking mechanism determines the physics of the all-optical switching. 80 The magnetization is not reversed by a 180 rotation, as in a standard recording media (transverse relaxation).…”

Section: B All-optical Switchingmentioning

confidence: 99%

Perspective: Ultrafast magnetism and THz spintronics

Walowski

Münzenberg

2016

Journal of Applied Physics

325

205

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This year the discovery of femtosecond demagnetization by laser pulses is 20 years old. For the first time, this milestone work by Bigot and coworkers gave insight directly into the time scales of microscopic interactions that connect the spin and electron system. While intense discussions in the field were fueled by the complexity of the processes in the past, it now became evident that it is a puzzle of many different parts. Rather than providing an overview that has been presented in previous reviews on ultrafast processes in ferromagnets, this perspective will show that with our current depth of knowledge the first applications are developed: THz spintronics and all-optical spin manipulation are becoming more and more feasible. The aim of this perspective is to point out where we can connect the different puzzle pieces of understanding gathered over 20 years to develop novel applications. Based on many observations in a large number of experiments. Differences in the theoretical models arise from the localized and delocalized nature of ferromagnetism. Transport effects are intrinsically non-local in spintronic devices and at interfaces. We review the need for multiscale modeling to address the processes starting from electronic excitation of the spin system on the picometer length scale and sub-femtosecond time scale, to spin wave generation, and towards the modeling of ultrafast phase transitions that altogether determine the response time of the ferromagnetic system. Today, our current understanding gives rise to the first usage of ultrafast spin physics for ultrafast magnetism control: THz spintronic devices. This makes the field of ultrafast spin-dynamics an emerging topic open for many researchers right now. Published by AIP Publishing. [http://dx

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Experimental Evidence of Chiral Ferrimagnetism in Amorphous GdCo Films

et al. 2018

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Inversion symmetry breaking has become a vital research area in modern magnetism with phenomena including the Rashba effect, spin Hall effect, and the Dzyaloshinskii-Moriya interaction (DMI)-a vector spin exchange. The latter one may stabilize chiral spin textures with topologically nontrivial properties, such as Skyrmions. So far, chiral spin textures have mainly been studied in helimagnets and thin ferromagnets with heavy-element capping. Here, the concept of chirality driven by interfacial DMI is generalized to complex multicomponent systems and demonstrated on the example of chiral ferrimagnetism in amorphous GdCo films. Utilizing Lorentz microscopy and X-ray magnetic circular dichroism spectroscopy, and tailoring thickness, capping, and rare-earth composition, reveal that 2 nm thick GdCo films preserve ferrimagnetism and stabilize chiral domain walls. The type of chiral domain walls depends on the rare-earth composition/saturation magnetization, enabling a possible temperature control of the intrinsic properties of ferrimagnetic domain walls.

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Ferrimagnetic Tb–Fe Alloy Thin Films: Composition and Thickness Dependence of Magnetic Properties and All-Optical Switching

Cited by 93 publications

References 65 publications

Double exchange bias in ferrimagnetic heterostructures

Double exchange bias in ferrimagnetic heterostructures

Perspective: Ultrafast magnetism and THz spintronics

Experimental Evidence of Chiral Ferrimagnetism in Amorphous GdCo Films

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