Your search keyword '"Schütz, Gisela"' showing total 556 results

1. Direct determination of the spin-polarization at buried interfaces using voltage dependent MOKE signals

Author

Miller, Michael, Nacke, Rene, Ilse, Sven, Schütz, Gisela, and Goering, Eberhard

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

Here, we report a novel and conceptually straightforward technique to detect the spin-polarization directly, with laser spot spatial resolution, at buried ferromagnet/insulator interfaces in ambient settings. This has been accomplished by monitoring the voltage-induced change of the longitudinal MOKE signal as a function of the applied magnetic field and applying an AC voltage across the interface. For the case where the spin polarization enters the VMOKE signal, a simple quantitative model is proposed. A distinct positive majority spin polarization has been found for Fe and Co, whereas Ni exhibits a negative minority spin polarization.

Published

2023

2. Pump--probe x-ray microscopy of photo-induced magnetization dynamics at MHz repetition rates

Author

Gerlinger, Kathinka, Pfau, Bastian, Hennecke, Martin, Kern, Lisa-Marie, Will, Ingo, Noll, Tino, Weigand, Markus, Gräfe, Joachim, Träger, Nick, Schneider, Michael, Günther, Christian M., Engel, Dieter, Schütz, Gisela, and Eisebitt, Stefan

Subjects

Condensed Matter - Materials Science

Abstract

We present time-resolved scanning x-ray microscopy measurements with picosecond photo-excitation via a tailored infrared pump laser at a scanning transmission x-ray microscope. Specifically, we image the laser-induced demagnetization and remagnetization of thin ferrimagnetic GdFe films proceeding on a few nanoseconds time scale. Controlling the heat load on the sample via additional reflector and heat-sink layers allows us to conduct destruction-free measurements at a repetition rate of \SI{50}{\mega\hertz}. Near-field enhancement of the photo-excitation and controlled annealing effects lead to laterally heterogeneous magnetization dynamics which we trace with \SI{30}{\nano\meter} spatial resolution. Our work opens new opportunities to study photo-induced dynamics on the nanometer scale, with access to picosecond to nanosecond timescales, which is of technological relevance, especially in the field of magnetism.

Published

2022

3. Role of substrate clamping on anisotropy and domain structure in the canted antiferromagnet $\alpha$-Fe$_2$O$_3$

Author

Wittmann, Angela, Gomonay, Olena, Litzius, Kai, Kaczmarek, Allison, Kossak, Alexander E., Wolf, Daniel, Lubk, Axel, Johnson, Tyler N., Tremsina, Elizaveta A., Churikova, Alexandra, Büttner, Felix, Wintz, Sebastian, Mawass, Mohamad-Assaad, Weigand, Markus, Kronast, Florian, Scipioni, Larry, Shepard, Adam, Newhouse-Illig, Ty, Greer, James A, Schütz, Gisela, Birge, Norman O., and Beach, Geoffrey S. D.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Antiferromagnets have recently been propelled to the forefront of spintronics by their high potential for revolutionizing memory technologies. For this, understanding the formation and driving mechanisms of the domain structure is paramount. In this work, we investigate the domain structure in a thin-film canted antiferromagnet $\alpha$-Fe$_2$O$_3$. We find that the internal destressing fields driving the formation of domains do not follow the crystal symmetry of $\alpha$-Fe$_2$O$_3$, but fluctuate due to substrate clamping. This leads to an overall isotropic distribution of the N\'eel order with locally varying effective anisotropy in antiferromagnetic thin films. Furthermore, we show that the weak ferromagnetic nature of $\alpha$-Fe$_2$O$_3$ leads to a qualitatively different dependence on magnetic field compared to collinear antiferromagnets such as NiO. The insights gained from our work serve as a foundation for further studies of electrical and optical manipulation of the domain structure of antiferromagnetic thin films., Comment: 9 pages, 5 figures

Published

2022

4. Terahertz spin-to-charge current conversion in stacks of ferromagnets and the transition-metal dichalcogenide NbSe$_2$

Author

Nádvorník, Lukáš, Gueckstock, Oliver, Braun, Lukas, Niu, Chengwang, Gräfe, Joachim, Richter, Gunther, Schütz, Gisela, Takagi, Hidenori, Seifert, Tom S., Kubaščík, Peter, Pandeya, Avanindra K., Anane, Abdelmadjid, Yang, Heejun, Bedoya-Pinto, Amilcar, Parkin, Stuart S. P., Wolf, Martin, Mokrousov, Yuriy, Nakamura, Hiroyuki, and Kampfrath, Tobias

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Transition-metal dichalcogenides (TMDCs) are an aspiring class of materials with unique electronic and optical properties and potential applications in spin-based electronics. Here, we use terahertz emission spectroscopy to study spin-to-charge current conversion (S2C) in the TMDC NbSe$_2$ in ultra-high-vacuum-grown F|NbSe$_2$ thin-film stacks, where F is a layer of ferromagnetic Fe or Ni. Ultrafast laser excitation triggers an ultrafast spin current that is converted into an in-plane charge current and, thus, a measurable THz electromagnetic pulse. The THz signal amplitude as a function of the NbSe$_2$ thickness shows that the measured signals are fully consistent with an ultrafast optically driven injection of an in-plane-polarized spin current into NbSe$_2$. Modeling of the spin-current dynamics reveals that a sizable fraction of the total S2C originates from the bulk of NbSe$_2$ with the same, negative, sign as the spin Hall angle of pure Nb. By quantitative comparison of the emitted THz radiation from F|NbSe$_2$ to F|Pt reference samples and the results of ab-initio calculations, we estimate that the spin Hall angle of NbSe$_2$ for an in-plane polarized spin current lies between -0.2% and -1.1%, while the THz spin-current relaxation length is of the order of a few nanometers.

Published

2022

5. Commensurate vortex core switching in magnetic nanodisks at Gigahertz frequencies

Author

Gypens, Pieter, Leliaert, Jonathan, Schütz, Gisela, and Van Waeyenberge, Bartel

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The development of future spintronic applications requires a thorough and fundamental understanding of the magnetisation dynamics. Of particular interest are magnetic nanodisks, in which the vortex state emerges as a stable spin configuration. Here, we focus on how the vortex core polarisation can be reversed periodically by an oscillating magnetic field, applied perpendicularly to the disk's surface. By means of micromagnetic simulations, we demonstrate the presence of several subharmonic switching modes, i.e., the commensurate ratio between the switching frequency of the core and the driving frequency. The underlying mechanism of this periodic behaviour depends on the disk thickness. For thin disks, the core switches periodically due to resonant excitation of radial spin wave modes, while it is due to the breathing mode in the case of thick disks. However, overlap of both modes impedes periodic vortex core switching. For thin disks, the threshold field amplitude required for periodic switching can be lowered to about 30~mT by increasing the disk diameter. For thick disks, in contrast, the minimal field is largely unaffected by the disk diameter, as only the energy density of a central region around the vortex core is relevant to excite the breathing mode. Our results contribute to the understanding of the switching mechanisms in magnetic nanodisks, which are of technological interest due to their potential in non-volatile memory devices.

Published

2021

6. Generation of Switchable Singular Beams with Dynamic Metasurfaces

Author

Yu, Ping, Li, Jianxiong, Li, Xin, Schuetz, Gisela, Hirscher, Michael, Zhang, Shuang, and Liu, Na

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Singular beams have attracted great attention due to their optical properties and broad applications from light manipulation to optical communications. However, there has been a lack of practical schemes with which to achieve switchable singular beams with sub-wavelength resolution using ultrathin and flat optical devices. In this work, we demonstrate the generation of switchable vector and vortex beams utilizing dynamic metasurfaces at visible frequencies. The dynamic functionality of the metasurface pixels is enabled by the utilization of magnesium nanorods, which possess plasmonic reconfigurability upon hydrogenation and dehydrogenation. We show that switchable vector beams of different polarization states and switchable vortex beams of different topological charges can be implemented through simple hydrogenation and dehydrogenation of the same metasurfaces. Furthermore, we demonstrate a two-cascade metasurface scheme for holographic pattern switching, taking inspiration from orbital angular momentum-shift keying. Our work provides an additional degree of freedom to develop high-security optical elements for anti-counterfeiting applications.

Published

2021

7. Dynamic Janus Metasurfaces in the Visible Spectral Region

Author

Yu, Ping, Li, Jianxiong, Zhang, Shuang, Jin, Zhongwei, Schuetz, Gisela, Qiu, Cheng-Wei, Hirscher, Michael, and Liu, Na

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Janus monolayers have long been captivated as a popular notion for breaking in-plane and out-of-plane structural symmetry. Originated from chemistry and materials science, the concept of Janus functions have been recently extended to ultrathin metasurfaces by arranging meta-atoms asymmetrically with respect to the propagation or polarization direction of the incident light. However, such metasurfaces are intrinsically static and the information they carry can be straightforwardly decrypted by scanning the incident light directions and polarization states once the devices are fabricated. In this Letter, we present a dynamic Janus metasurface scheme in the visible spectral region. In each super unit cell, three plasmonic pixels are categorized into two sets. One set contains a magnesium nanorod and a gold nanorod that are orthogonally oriented with respect to each other, working as counter pixels. The other set only contains a magnesium nanorod. The effective pixels on the Janus metasurface can be reversibly regulated by hydrogenation/dehydrogenation of the magnesium nanorods. Such dynamic controllability at visible frequencies allows for flat optical elements with novel functionalities including beam steering, bifocal lensing, holographic encryption, and dual optical function switching.

Published

2021

8. Freezing and thawing magnetic droplet solitons

Author

Ahlberg, Martina, Chung, Sunjae, Jiang, Sheng, Le, Q. Tuan, Khymyn, Roman, Mazraati, Hamid, Weigand, Markus, Bykova, Iuliia, Groß, Felix, Goering, Eberhard, Schütz, Gisela, Gräfe, Joachim, and Åkerman, Johan

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Magnetic droplets are non-topological magnetodynamical solitons displaying a wide range of complex dynamic phenomena with potential for microwave signal generation. Bubbles, on the other hand, are internally static cylindrical magnetic domains, stabilized by external fields and magnetostatic interactions. In its original theory, the droplet was described as an imminently collapsing bubble stabilized by spin transfer torque and, in its zero-frequency limit, as equivalent to a bubble. Without nanoscale lateral confinement, pinning, or an external applied field, such a nanobubble is unstable, and should collapse. Here, we show that we can freeze dynamic droplets into static nanobubbles by decreasing the magnetic field. While the bubble has virtually the same resistance as the droplet, all signs of low-frequency microwave noise disappear. The transition is fully reversible and the bubble can be thawed back into a droplet if the magnetic field is increased under current. Whereas the droplet collapses without a sustaining current, the bubble is highly stable and remains intact for days without external drive. Electrical measurements are complemented by direct observation using scanning transmission x-ray microscopy, which corroborates the analysis and confirms that the bubble is stabilized by pinning., Comment: 23 pages, 5 figures

Published

2021

9. Maskless off-axis X-ray Holography

Author

Keskinbora, Kahraman, Levitan, Abraham, Schütz, Gisela, and Comin, Riccardo

Subjects

Physics - Optics, Condensed Matter - Materials Science

Abstract

Off-axis X-ray holography is a lensless imaging technique that allows unambiguous retrieval of an object's exit-wave function with high fidelity. It has been used with great success to study nanoscale phenomena and spatio-temporal dynamics in solids, with sensitivity to the phase component of electronic and magnetic textures. However, the method requires patterning a nanostructured holography mask directly onto the sample. This invasive fabrication process is labor-intensive and defines a fixed field of view, limiting the range of applicable samples and diminishing the signal-to-noise ratio at high-resolution. In this work, we propose using wavefront-shaping X-ray diffractive optics to create a spatially structured probe with full control of its phase at the sample plane, obviating the need for a holography mask. We demonstrate in silico that the method can image nanoscale structures and magnetic textures. The proposed holography route can image extended regions of interest, enabling the investigation of a broad range of physical phenomena at the nanoscale including magnetism and electronic phase coexistence in quantum materials. We further envisage applications in phase-contrast imaging of other weakly absorbing objects in the realm of soft and biological matter research., Comment: 21 pages w/ supporting information, 8 figures total - 3 figures in main text

Published

2021

10. X‑ray Microspectroscopy and Ptychography on Nanoscale Structures in Rock Varnish

Author

Förster, Jan-David, Bykova, Iuliia, Macholdt, Dorothea S, Jochum, Klaus Peter, Kappl, Michael, Kilcoyne, AL David, Müller, Maren, Sorowka, Antje, Weber, Bettina, Weigand, Markus, Schütz, Gisela, Andreae, Meinrat O, and Pöhlker, Christopher

Subjects

Chemical Sciences, Engineering, Technology, Physical Chemistry

Abstract

X-ray microspectroscopy is a powerful analytical method in geoscientific and environmental research as it provides a unique combination of nanoscale imaging with high spectroscopic sensitivity at relatively low beam-related sample damage. In this study, "classical"scanning transmission soft X-ray microscopy (STXM) with X-ray absorption spectroscopy and the recently established soft X-ray ptychography are applied to the analysis of selected rock varnish samples from urban and arid desert environments. X-ray ptychography enhances the spatial resolution relative to STXM by up to 1 order of magnitude. With its high chemical sensitivity, it can resolve nanoscale differences in valence states of the key varnish elements manganese (Mn) and iron. Our results emphasize the complex nanoarchitecture of rock varnish as well as the diverse mineralogy of the Mn oxy-hydroxide matrix and its embedded dust grains. In contrast to the fast-growing urban varnish, the slow-growing arid desert varnish revealed a remarkable nanoscale stratification of alternating Mn valence states, providing hints on the layer-wise and still enigmatic growth process.

Published

2021

11. Observation of a possible diluted ferromagnetism above room temperature in cobalt-substituted LaTa(O,N)3-d

Author

Bubeck, Cora, Goering, Eberhard, Lawitzki, Robert, Küster, Kathrin, Sigle, Wilfried, Widenmeyer, Marc, Starke, Ulrich, Ritter, Clemens, Cuello, Gabriel J., Nagel, Peter, Merz, Michael, Schuppler, Stefan, Schütz, Gisela, and Weidenkaff, Anke

Subjects

Condensed Matter - Materials Science

Abstract

Since 2000, the intensive effort in materials research to develop a diluted magnetic semiconductor exhibiting high-temperature (HT) ferromagnetism above room temperature was not successful. Here, the possible first bulk diluted HT-ferromagnetic non-metallic materials, based on the perovskite-type oxynitrides LaTa1-xCox(O,N)3-d (x = 0.01, 0.03, 0.05) are realized. The Curie temperature of the synthesized powders exceeds 600 K and the sample magnetizations are large enough to be directly attracted by permanent magnets. Cobalt clusters as a possible source for the observed HT-ferromagnetism can be excluded, since all applied characterization methods verify phase purity. Applied conventional and element-specific magnetometry imply ferromagnetic intermediate spin (IS) Co3+ which is included in a ferromagnetic host matrix. This indicates a complex magnetic interplay between the existing crystal structure, the observed anionic vacancies, and the introduced cobalt ions. These results lay the foundation for the experimental investigation and design of further diluted HT-ferromagnetic semiconductors., Comment: submitted to journal

Published

2020

12. Magnetic phase transition in dimer-based metal-organic frameworks through structural modulation

Author

Kim, Sunghyun, Schütz, Gisela, Son, Kwanghyo, and Oh, Hyunchul

Published

2023

13. Real space observation of magnon interaction with driven space-time crystals

Author

Träger, Nick, Gruszecki, Paweł, Lisiecki, Filip, Groß, Felix, Förster, Johannes, Weigand, Markus, Głowiński, Hubert, Kuświk, Piotr, Dubowik, Janusz, Schütz, Gisela, Krawczyk, Maciej, and Gräfe, Joachim

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The concept of Space-Time Crystals (STC), i.e. translational symmetry breaking in time and space, was recently proposed and experimentally demonstrated for quantum systems. Here, we transfer this concept to magnons and experimentally demonstrate a driven STC at room temperature. The STC is realized by strong homogeneous micro-wave pumping of a micron-sized permalloy (Py) stripe and is directly imaged by Scanning Transmission X-ray Microscopy (STXM). For a fundamental understanding of the formation of the STC, micromagnetic simulations are carefully adapted to model the experimental findings. Beyond the mere generation of a STC, we observe the formation of a magnonic band structure due to back folding of modes at the STC's Brillouin zone boundaries. We show interactions of magnons with the STC that appear as lattice scattering. This results in the generation of ultra short spin waves down to 100 nm wavelength that cannot be described by classical dispersion relations for linear spin wave excitations. We expect that room temperature STCs will be a useful tool to investigate non-linear wave physics, as they can be easily generated and manipulated to control their spatial and temporal band structure.

Published

2019

14. Reconfigurable sub-micron spin-wave majority gate with electrical transducers

Author

Talmelli, Giacomo, Devolder, Thibaut, Träger, Nick, Förster, Johannes, Wintz, Sebastian, Weigand, Markus, Stoll, Hermann, Heyns, Marc, Schütz, Gisela, Radu, Iuliana, Gräfe, Joachim, Ciubotaru, Florin, and Adelmann, Christoph

Subjects

Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Emerging Technologies

Abstract

Spin waves are excitations in ferromagnetic media that have been proposed as information carriers in hybrid spintronic devices with much lower operation power than conventional charge-based electronics. Their wave nature can be exploited in majority gates by using interference for computation. However, a scalable spin-wave majority gate that can be co-integrated alongside conventional electronics is still lacking. Here, we demonstrate a sub-micron inline spin-wave majority gate with fan-out. Time-resolved imaging of the magnetization dynamics by scanning transmission x-ray microscopy illustrates the device operation. All-electrical spin-wave spectroscopy further demonstrates majority gates with sub-micron dimensions, reconfigurable input and output ports, and frequency-division multiplexing. Challenges for hybrid spintronic computing systems based on spin-wave majority gates are discussed., Comment: This project has received funding from the European Union's Horizon 2020 research and innovation program under grant agreement No. 801055 "Spin Wave Computing for Ultimately-Scaled Hybrid Low-Power Electronics" - CHIRON

Published

2019

15. N\'eel-type skyrmions and their current-induced motion in van der Waals ferromagnet-based heterostructures

Author

Park, Tae-Eon, Peng, Licong, Liang, Jinghua, Hallal, Ali, Yasin, Fehmi Sami, Zhang, Xichao, Kim, Sung Jong, Song, Kyung Mee, Kim, Kwangsu, Weigand, Markus, Schuetz, Gisela, Finizio, Simone, Raabe, Joerg, Garcia, Karin, Xia, Jing, Zhou, Yan, Ezawa, Motohiko, Liu, Xiaoxi, Chang, Joonyeon, Koo, Hyun Cheol, Kim, Young Duck, Chshiev, Mairbek, Fert, Albert, Yang, Hongxin, Yu, Xiuzhen, and Woo, Seonghoon

Subjects

Condensed Matter - Materials Science

Abstract

Since the discovery of ferromagnetic two-dimensional (2D) van der Waals (vdW) crystals, significant interest on such 2D magnets has emerged, inspired by their appealing properties and integration with other 2D family for unique heterostructures. In known 2D magnets, spin-orbit coupling (SOC) stabilizes perpendicular magnetic anisotropy (PMA). Such a strong SOC could also lift the chiral degeneracy, leading to the formation of topological magnetic textures such as skyrmions through the Dzyaloshinskii-Moriya interaction (DMI). Here, we report the experimental observation of N\'eel-type chiral magnetic skyrmions and their lattice (SkX) formation in a vdW ferromagnet Fe3GeTe2 (FGT). We demonstrate the ability to drive individual skyrmion by short current pulses along a vdW heterostructure, FGT/h-BN, as highly required for any skyrmion-based spintronic device. Using first principle calculations supported by experiments, we unveil the origin of DMI being the interfaces with oxides, which then allows us to engineer vdW heterostructures for desired chiral states. Our finding opens the door to topological spin textures in the 2D vdW magnet and their potential device application., Comment: 26 pages, 5 figures

Published

2019

16. Formation of a super-dense hydrogen monolayer on mesoporous silica

Author

Balderas-Xicohténcatl, Rafael, Lin, Hung-Hsuan, Lurz, Christian, Daemen, Luke, Cheng, Yongqiang, Cychosz Struckhoff, Katie, Guillet-Nicolas, Remy, Schütz, Gisela, Heine, Thomas, Ramirez-Cuesta, Anibal J., Thommes, Matthias, and Hirscher, Michael

Published

2022

17. Magnons in a Quasicrystal: Propagation, Localization and Extinction of Spin Waves in Fibonacci Structures

Author

Lisiecki, Filip, Rychły, Justyna, Kuświk, Piotr, Głowiński, Hubert, Kłos, Jarosław W., Groß, Felix, Bykova, Iuliia, Weigand, Markus, Zelent, Mateusz, Goering, Eberhard, Schütz, Gisela, Krawczyk, Maciej, Stobiecki, Feliks, Dubowik, Janusz, and Gräfe, Joachim

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Magnonic quasicrystals exceed the possibilities of spin wave (SW) manipulation offered by regular magnonic crystals, because of their more complex SW spectra with fractal characteristics. Here, we report the direct x-ray microscopic observation of propagating SWs in a magnonic quasicrystal, consisting of dipolarly coupled permalloy nanowires arranged in a one-dimensional Fibonacci sequence. SWs from the first and second band as well as evanescent waves from the band gap between them are imaged. Moreover, additional mini-band gaps in the spectrum are demonstrated, directly indicating an influence of the quasiperiodicity of the system. The experimental results are interpreted using numerical calculations and we deduce a simple model to estimate the frequency position of the magnonic gaps in quasiperiodic structures. The demonstrated features of SW spectra in one-dimensional magnonic quasicrystals allows utilizing this class of metamaterials for magnonics and makes them an ideal basis for future applications., Comment: 10 pages, 6 figures

Published

2018

18. X-Ray Microscopy of Spin Wave Focusing using a Fresnel Zone Plate

Author

Gräfe, Joachim, Decker, Martin, Keskinbora, Kahraman, Noske, Matthias, Gawronski, Przemysław, Stoll, Hermann, Back, Christian H., Goering, Eberhard J., and Schütz, Gisela

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Magnonics, i.e. the artificial manipulation of spin waves, is a flourishing field of research with many potential uses in data processing within reach. Apart from the technological applications the possibility to directly influence and observe these types of waves is of great interest for fundamental research. Guidance and steering of spin waves has been previously shown and lateral spin wave confinement has been achieved. However, true spin wave focusing with both lateral confinement and increase in amplitude has not been shown before. Here, we show for the first time spin wave focusing by realizing a Fresnel zone plate type lens. Using x-ray microscopy we are able to directly image the propagation of spin waves into the nanometer sized focal spot. Furthermore, we observe that the focal spot can be freely moved in a large area by small variations of the bias field. Thus, this type of lens provides a steerable intense nanometer sized spin wave source. Potentially, this could be used to selectively illuminate magnonic devices like nano oscillators with a steerable spin wave beam.

Published

2017

19. Direct observation of magnetic droplet solitons in all-perpendicular spin torque nano-oscillators

Author

Chung, Sunjae, Le, Q. Tuan, Ahlberg, Martina, Weigand, Markus, Bykova, Iuliia, Awad, Ahmad A., Mazraati, Hamid, Houshang, Afshin, Jiang, Sheng, Nguyen, T. N. Anh, Goering, Eberhard, Schütz, Gisela, Gräfe, Joachim, and Åkerman, Johan

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Magnetic droplets are non-topological dynamical solitons that can be nucleated and sustained in nano-contact based spin torque nano-oscillators (NC-STNOs) with perpendicular anisotropy free layers. While originally predicted in all-perpendicular NC-STNOs, all experimental demonstrations have so far relied on orthogonal devices with an in-plane polarizing layer that requires a strong magnetic field for droplet nucleation. Here, we instead show the nucleation and sustained operation of magnetic droplets in all-perpendicular NC-STNOs in modest perpendicular fields and over a wide range of nano-contact size. The droplet is observed electrically as an intermediate resistance state accompanied by broadband low-frequency microwave noise. Using canted fields, which introduce a non-zero relative angle between the free and fixed layer, the actual droplet precession frequency can also be determined. Finally, the droplet size, its perimeter width, and its fully reversed core are directly observed underneath a 80 nm diameter nano-contact using scanning transmission x-ray microscopy on both the Ni and Co edges. The droplet diameter is 150 nm, i.e. almost twice the nominal size of the nano-contact, and the droplet has a perimeter width of about 70 nm.

Published

2017

20. Current‐Induced Skyrmion Generation through Morphological Thermal Transitions in Chiral Ferromagnetic Heterostructures

Author

Lemesh, Ivan, Litzius, Kai, Böttcher, Marie, Bassirian, Pedram, Kerber, Nico, Heinze, Daniel, Zázvorka, Jakub, Büttner, Felix, Caretta, Lucas, Mann, Maxwell, Weigand, Markus, Finizio, Simone, Raabe, Jörg, Im, Mi‐Young, Stoll, Hermann, Schütz, Gisela, Dupé, Bertrand, Kläui, Mathias, and Beach, Geoffrey SD

Subjects

Quantum Physics, Physical Sciences, Dzyaloshinkii-Moriya interaction, magnetic domains, multilayers, perpendicular magnetic anisotropy, skyrmions, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Magnetic skyrmions promise breakthroughs in future memory and computing devices due to their inherent stability and small size. Their creation and current driven motion have been recently observed at room temperature, but the key mechanisms of their formation are not yet well-understood. Here it is shown that in heavy metal/ferromagnet heterostructures, pulsed currents can drive morphological transitions between labyrinth-like, stripe-like, and skyrmionic states. Using high-resolution X-ray microscopy, the spin texture evolution with temperature and magnetic field is imaged and it is demonstrated that with transient Joule heating, topological charges can be injected into the system, driving it across the stripe-skyrmion boundary. The observations are explained through atomistic spin dynamic and micromagnetic simulations that reveal a crossover to a global skyrmionic ground state above a threshold magnetic field, which is found to decrease with increasing temperature. It is demonstrated how by tuning the phase stability, one can reliably generate skyrmions by short current pulses and stabilize them at zero field, providing new means to create and manipulate spin textures in engineered chiral ferromagnets.

Published

2018

21. Freezing and thawing magnetic droplet solitons

Author

Ahlberg, Martina, Chung, Sunjae, Jiang, Sheng, Frisk, Andreas, Khademi, Maha, Khymyn, Roman, Awad, Ahmad A., Le, Q. Tuan, Mazraati, Hamid, Mohseni, Majid, Weigand, Markus, Bykova, Iuliia, Groß, Felix, Goering, Eberhard, Schütz, Gisela, Gräfe, Joachim, and Åkerman, Johan

Published

2022

22. Micromachining of Al2O3 thin films via laser drilling and plasma etching for interfacing copper

Author

Dogan, Gül, Chiu, Frank, Chen, Sam U.H., David, Mebil R.T., Michalowski, Andreas, Schänzel, Michael, Silber, Christian, Schütz, Gisela, Grévent, Corinne, and Keskinbora, Kahraman

Published

2021

23. Skyrmion Hall Effect Revealed by Direct Time-Resolved X-Ray Microscopy

Author

Litzius, Kai, Lemesh, Ivan, Krüger, Benjamin, Bassirian, Pedram, Caretta, Lucas, Richter, Kornel, Büttner, Felix, Sato, Koji, Tretiakov, Oleg A., Förster, Johannes, Reeve, Robert M., Weigand, Markus, Bykova, Iuliia, Stoll, Hermann, Schütz, Gisela, Beach, Geoffrey S. D., and Kläui, Mathias

Subjects

Condensed Matter - Materials Science

Abstract

Magnetic skyrmions are highly promising candidates for future spintronic applications such as skyrmion racetrack memories and logic devices. They exhibit exotic and complex dynamics governed by topology and are less influenced by defects, such as edge roughness, than conventionally used domain walls. In particular, their finite topological charge leads to a predicted "skyrmion Hall effect", in which current-driven skyrmions acquire a transverse velocity component analogous to charged particles in the conventional Hall effect. Here, we present nanoscale pump-probe imaging that for the first time reveals the real-time dynamics of skyrmions driven by current-induced spin orbit torque (SOT). We find that skyrmions move at a well-defined angle {\Theta}_{SH} that can exceed 30{\deg} with respect to the current flow, but in contrast to theoretical expectations, {\Theta}_{SH} increases linearly with velocity up to at least 100 m/s. We explain our observation based on internal mode excitations in combination with a field-like SOT, showing that one must go beyond the usual rigid skyrmion description to unravel the dynamics., Comment: pdf document arxiv_v1.1. 24 pages (incl. 9 figures and supplementary information)

Published

2016

24. Enhanced Non-Adiabaticity in Vortex Cores due to the Emergent Hall Effect

Author

Bisig, André, Akosa, Collins Ashu, Moon, Jung-Hwan, Rhensius, Jan, Moutafis, Christoforos, von Bieren, Arndt, Heidler, Jakoba, Kiliani, Gillian, Kammerer, Matthias, Curcic, Michael, Weigand, Markus, Tyliszczak, Tolek, Van Waeyenberge, Bartel, Stoll, Hermann, Schütz, Gisela, Lee, Kyung-Jin, Manchon, Aurelien, and Kläui, Mathias

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We present a combined theoretical and experimental study, investigating the origin of the enhanced non-adiabaticity of magnetic vortex cores. Scanning transmission X-ray microscopy is used to image the vortex core gyration dynamically to measure the non-adiabaticity with high precision, including a high confidence upper bound. Using both numerical computations and analytical derivations, we show that the large non-adiabaticity parameter observed experimentally can be explained by the presence of local spin currents arising from a texture-induced emergent Hall effect. This enhanced non-adiabaticity is only present in two- and three-dimensional magnetic textures such as vortices and skyrmions and absent in one-dimensional domain walls, in agreement with experimental observations., Comment: 6 pages, 3 figures

Published

2015

25. Spin wave mediated unidirectional Vortex Core Reversal by Two Orthogonal Monopolar Field Pulses: The Essential Role of Three-dimensional Magnetization Dynamics

Author

Noske, Matthias, Stoll, Hermann, Fähnle, Manfred, Gangwar, Ajay, Woltersdorf, Georg, Slavin, Andrei, Weigand, Markus, Dieterle, Georg, Förster, Johannes, Back, Christian H., and Schütz, Gisela

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter

Abstract

Scanning transmission x-ray microscopy is employed to investigate experimentally the reversal of the magnetic vortex core polarity in cylindrical Ni81Fe19 nanodisks triggered by two orthogonal monopolar magnetic field pulses with peak amplitude $B_0$, pulse length ${\tau}$=60 ps and delay time ${\Delta}$t in the range from -400 ps to +400 ps between the two pulses. The two pulses are oriented in-plane in the x- and y-direction. We have experimentally studied vortex core reversal as function of $B_0$ and ${\Delta}$t. The resulting phase diagram shows large regions of unidirectional vortex core switching where the switching threshold is modulated due to resonant amplification of azimuthal spin waves. The switching behavior changes dramatically depending on whether the first pulse is applied in the x- or the y-direction. This asymmetry can be reproduced by three-dimensional micromagnetic simulations but not by two-dimensional simulations. This behavior demonstrates that in contrast to previous experiments on vortex core reversal the three-dimensionality in the dynamics is essential here.

Published

2015

26. Three-dimensional Character of the Magnetization Dynamics in Magnetic Vortex Structures - Hybridization of Flexure Gyromodes with Spin Waves

Author

Noske, Matthias, Stoll, Hermann, Fähnle, Manfred, Gangwar, Ajay, Woltersdorf, Georg, Slavin, Andrei, Weigand, Markus, Dieterle, Georg, Förster, Johannes, Back, Christian H., and Schütz, Gisela

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Three-dimensional linear spin-wave eigenmodes of a Permalloy disk having finite thickness are studied by micromagnetic simulations based on the Landau-Lifshitz-Gilbert equation. The eigenmodes found in the simulations are interpreted as linear superpositions (hybridizations) of 'approximate' three-dimensional eigenmodes, which are the fundamental gyromode $G_0$, the spin-wave modes and the higher-order gyromodes $G_N$ (flexure modes), the thickness dependence of which is represented by perpendicular standing spin waves. This hybridization leads to new and surprising dependencies of the mode frequencies on the disk thickness. The three-dimensional character of the eigenmodes is essential to explain the recent experimental results on vortex-core reversal observed in relatively thick Permalloy disks.

Published

2015

27. Disentangling different interfacial effects of reduced thin layer magnetizations.

Author

Ilse, Sven Erik, Nacke, René, Schütz, Gisela, and Goering, Eberhard

Subjects

MAGNETIC transitions, MAGNETIC properties, INTERFACIAL roughness, DEPTH profiling, CHROMIUM oxide

Abstract

Thin buried magnetic layers ranging from thicknesses of a few atomic monolayers to several nanometers are omnipresent in the fields of magnetism and spintronics. For the functionality and fine tuning of devices build with such layers, exact knowledge of the depth dependent magnetic properties is essential. Especially the interfacial magnetic properties are important. Hence, understanding how magnetism is affected by structural variations, such as thickness or interface roughness, is mandatory. In this study, we use x-ray resonant magnetic reflectometry and magnetometry to study the high-resolution depth dependent magnetization profiles of thin magnetic transition metal layers sandwiched between an oxide and chromium layer. Compared to bulk materials, the room temperature saturation magnetization of these layers is reduced by up to 67%. These reductions are extremely sensitive to small structural variations. From the magnetic depth profiles, we disentangle different effects contributing to the magnetization reduction and the exact magnetic properties of the interface. [ABSTRACT FROM AUTHOR]

Published

2024

28. Influence of Magnetic Sublattice Ordering on Skyrmion Bubble Stability in 2D Magnet Fe5GeTe2.

Author

Birch, Max T., Yasin, Fehmi S., Litzius, Kai, Powalla, Lukas, Wintz, Sebastian, Schulz, Frank, Kossak, Alexander E., Weigand, Markus, Scholz, Tanja, Lotsch, Bettina V., Schütz, Gisela, Yu, Xiuzhen Z., and Burghard, Marko

Published

2024

29. Nanomagnetismus im Röntgenlicht

Author

Schütz, Gisela, Duchardt, Deborah, editor, Bossmann, Andrea B., editor, and Denz, Cornelia, editor

Published

2019

30. Magnetic and microstructural properties of anisotropic MnBi magnets compacted by spark plasma sintering

Author

Chen, Yu-Chun, Gregori, Giuliano, Rheingans, Bastian, Huang, Wenting, Kronmüller, Helmut, Schütz, Gisela, and Goering, Eberhard

Published

2020

31. Effect of the soft layer thickness on magnetization reversal process of exchange-spring nanomagnet patterns

Author

Son, Kwanghyo, Schütz, Gisela, and Goering, Eberhard

Published

2020

32. Element-resolved study on the evolution of magnetic response in FexN compounds

Author

Chen, Yu-Chun, Gölden, Dominik, Dirba, Imants, Huang, Meng-Jie, Gutfleisch, Oliver, Nagel, Peter, Merz, Michael, Schuppler, Stefan, Schütz, Gisela, Alff, Lambert, and Goering, Eberhard

Published

2020

33. Fabrication and temperature-dependent magnetic properties of large-area L10-FePt/Co exchange-spring magnet nanopatterns

Author

Son, Kwanghyo and Schütz, Gisela

Published

2020

34. Coherent Magnons with Giant Nonreciprocity at Nanoscale Wavelengths

Author

Gallardo, Rodolfo, primary, Weigand, Markus, additional, Schultheiss, Katrin, additional, Kakay, Attila, additional, Mattheis, Roland, additional, Raabe, Jörg, additional, Schütz, Gisela, additional, Deac, Alina, additional, Lindner, Jürgen, additional, and Wintz, Sebastian, additional

Published

2024

35. Control of stripe, skyrmion and skyrmionium formation in the 2D magnet Fe3−xGeTe2 by varying composition

Author

Birch, Max T, primary, Powalla, Lukas, additional, Litzius, Kai, additional, Nehruji, Vanessa, additional, Hovorka, Ondrej, additional, Wintz, Sebastian, additional, Schulz, Frank, additional, Mayoh, Daniel A, additional, Balakrishnan, Geetha, additional, Weigand, Markus, additional, Burghard, Marko, additional, and Schütz, Gisela, additional

Published

2024

36. Unidirectional sub-100 ps magnetic vortex core reversal

Author

Noske, Matthias, Gangwar, Ajay, Stoll, Hermann, Kammerer, Matthias, Sproll, Markus, Dieterle, Georg, Weigand, Markus, Fähnle, Manfred, Woltersdorf, Georg, Back, Christian H., and Schütz, Gisela

Subjects

Condensed Matter - Other Condensed Matter

Abstract

The magnetic vortex structure, an important ground state configuration in micron and sub-micron sized ferromagnetic thin film platelets, is characterized by a curling in-plane magnetization and, in the center, a minuscule region with out-of-plane magnetization, the vortex core, which points either up or down. It has already been demonstrated that the vortex core polarity can be reversed with external AC magnetic fields, frequency-tuned to the (sub-GHz) gyrotropic eigenmode or to (multi-GHz) azimuthal spin wave modes, where reversal times in the sub-ns regime can be realized. This fast vortex core switching may also be of technological interest as the vortex core polarity can be regarded as one data bit. Here we experimentally demonstrate that unidirectional vortex core reversal by excitation with sub-100 ps long orthogonal monopolar magnetic pulse sequences is possible in a wide range of pulse lengths and amplitudes. The application of such short digital pulses is the favourable excitation scheme for technological applications. Measured phase diagrams of this unidirectional, spin wave mediated vortex core reversal are in good qualitative agreement with phase diagrams obtained from micromagnetic simulations. The time dependence of the reversal process, observed by time-resolved scanning transmission X-ray microscopy indicates a switching time of 100 ps and fits well with our simulations. The origin of the asymmetric response to clockwise and counter clockwise excitation which is a prerequisite for reliable unidirectional switching is discussed, based on the gyromode - spin wave coupling.

Published

2014

37. The role of temperature and drive current in skyrmion dynamics

Author

Litzius, Kai, Leliaert, Jonathan, Bassirian, Pedram, Rodrigues, Davi, Kromin, Sascha, Lemesh, Ivan, Zazvorka, Jakub, Lee, Kyu-Joon, Mulkers, Jeroen, Kerber, Nico, Heinze, Daniel, Keil, Niklas, Reeve, Robert M., Weigand, Markus, Van Waeyenberge, Bartel, Schütz, Gisela, Everschor-Sitte, Karin, Beach, Geoffrey S. D., and Kläui, Mathias

Published

2020

38. Low-amplitude magnetic vortex core reversal by non-linear interference between azimuthal spin waves and the vortex gyromode

Author

Sproll, Markus, Noske, Matthias, Bauer, Hans, Kammerer, Matthias, Gangwar, Ajay, Dieterle, Georg, Weigand, Markus, Stoll, Hermann, Back, Christian H., and Schütz, Gisela

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter

Abstract

We demonstrate a non-linear interference due to an active 'dual frequency' excitation of both, the sub-GHz vortex gyromode and multi-GHz magneto-static spin waves in ferromagnetic micrometer sized platelets in the vortex state. When the sub-GHz vortex gyromode is excited simultaneously a significant broadband reduction of the switching threshold for spin wave mediated vortex core reversal is observed in both, experiments and micromagnetic simulations. Consequently, the magnetic field amplitudes required for vortex core reversal can be lowered by nearly one order of magnitude. Moreover, additional spin wave resonance frequencies are found which emerge only if the vortex gyromode is actively excited simultaneously which can be explained by frequency doubling and by the broken symmetry of the vortex state., Comment: 5 pages, 4 figures

Published

2013

39. Wave modes of collective vortex gyration in dipolar-coupled-dot-array magnonic crystals

Author

Han, Dong-Soo, Vogel, Andreas, Jung, Hyunsung, Lee, Ki-Suk, Weigand, Markus, Stoll, Hermann, Schütz, Gisela, Fischer, Peter, Meier, Guido, and Kim, Sang-Koog

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Lattice vibration modes are collective excitations in periodic arrays of atoms or molecules. These modes determine novel transport properties in solid crystals. Analogously, in periodical arrangements of magnetic vortex-state disks, collective vortex motions have been predicted. Here, we experimentally observe wave modes of collective vortex gyration in one-dimensional (1D) chains of periodic disks using time-resolved scanning transmission x-ray microscopy. The observed modes are interpreted based on micromagnetic simulation and numerical calculation of coupled Thiele equations. Dispersion of the modes is found to be strongly affected by both vortex polarization and chirality ordering, as revealed by the explicit analytical form of 1D infinite chains. A thorough understanding thereof is fundamental both for lattice vibrations and vortex dynamics, which we demonstrate for 1D magnonic crystals. Such magnetic disk arrays with vortex-state ordering, referred to as magnetic metastructure, offer potential implementation into information processing devices., Comment: 39pagae, 7 figures (including two supplementary figures)

Published

2013

40. Ion beam lithography for Fresnel zone plates in X-ray microscopy

Author

Keskinbora, Kahraman, Grévent, Corinne, Bechtel, Michael, Weigand, Markus, Goering, Eberhard, Nadzeyka, Achim, Peto, Lloyd, Rehbein, Stefan, Schneider, Gerd, Follath, Rolf, Vila-Comamala, Joan, Yan, Hanfei, and Schütz, Gisela

Subjects

Physics - Optics

Abstract

Fresnel Zone Plates (FZP) are to date very successful focusing optics for X-rays. Established methods of fabrication are rather complex and based on electron beam lithography (EBL). Here, we show that ion beam lithography (IBL) may advantageously simplify their preparation. A FZP operable from the extreme UV to the limit of the hard X-ray was prepared and tested from 450 eV to 1500 eV. The trapezoidal profile of the FZP favorably activates its 2nd order focus. The FZP with an outermost zone width of 100 nm allows the visualization of features down to 61, 31 and 21 nm in the 1st, 2nd and 3rd order focus respectively. Measured efficiencies in the 1st and 2nd order of diffraction reach the theoretical predictions.

Published

2012

41. 200 ps Vortex Core Reversal by Azimuthal Spin Waves

Author

Kammerer, Matthias, Stoll, Hermann, Noske, Matthias, Sproll, Markus, Weigand, Markus, Woltersdorf, Georg, and Schütz, Gisela

Subjects

Condensed Matter - Other Condensed Matter

Abstract

Spin wave mediated vortex core reversal has been investigated by time-resolved scanning transmission X-ray microscopy (STXM). Movies showing the development of the spin wave and vortex core magnetization dynamics during unidirectional vortex core reversal could be taken in Permalloy discs, 1.6 \mu m in diameter and 50 nm thick, during excitation with rotating ac field bursts of one period duration at 4.5 GHz and with amplitudes up to 4 mT. Unidirectional switching is achieved by taking advantage of an asymmetry for CW or CCW excitation caused by the gyrofield. The differences in the magnetization dynamics due to this asymmetry could be imaged during continuous excitation with multi-GHz rotating fields. All our experimental results are in good agreement with micromagnetic simulations. In addition, for the sample geometry given above, simulations reveal a lower limit of about 200 ps for the time of unidirectional vortex core switching, which cannot be overcome by shortening the excitation length or by increasing the excitation amplitude. We explain this limitation by the finite time needed for an energy transfer of the global excitation towards the center of the sample. Thus smaller samples will allow for much shorter vortex core reversal times.

Published

2011

42. Observation of non-linear magnetic vortex gyration by X-ray microscopy and micromagnetic simulations

Author

Vansteenkiste, Arne, Van de Wiele, Ben, Weigand, Markus, Stoll, Hermann, Chou, Kang W., Tyliszczak, Tolek, Woltersdorf, Georg, Back, Christian H., Schütz, Gisela, and Van Waeyenberge, Bartel

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

Magnetic vortex gyration in a 500 nm wide, 50 nm thick Permalloy square platelet was investigated using time-resolved scanning transmission x-ray microscopy and micromagnetic simulations. The response of the vortex core on an in-plane oscillating magnetic field was studied as a function of the excitation frequency and amplitude. Non-linear behavior was observed in the form of a redshift of the gyrotropic resonance. I.e., when the excitation amplitude was increased, the resonance frequency was found to decrease. The nonlinearity is in agreement with extensive micromagnetic simulations. This work complements previous reports on thinner nanostructures where a frequency blueshift was observed.

Published

2011

43. Magnetic Vortex Core Reversal by Excitation of Spin Waves

Author

Kammerer, Matthias, Weigand, Markus, Curcic, Michael, Noske, Matthias, Sproll, Markus, Stoll, Hermann, Vansteenkiste, Arne, Van Waeyenberge, Bartel, Woltersdorf, Georg, Back, Christian, and Schuetz, Gisela

Subjects

Condensed Matter - Other Condensed Matter

Abstract

Micron-sized magnetic platelets in the flux closed vortex state are characterized by an in-plane curling magnetization and a nanometer-sized perpendicularly magnetized vortex core. Having the simplest non-trivial configuration, these objects are of general interest to micromagnetics and may offer new routes for spintronics applications. Essential progress in the understanding of nonlinear vortex dynamics was achieved when low-field core toggling by excitation of the gyrotropic eigenmode at sub-GHz frequencies was established. At frequencies more than an order of magnitude higher vortex state structures possess spin wave eigenmodes arising from the magneto-static interaction. Here we demonstrate experimentally that the unidirectional vortex core reversal process also occurs when such azimuthal modes are excited. These results are confirmed by micromagnetic simulations which clearly show the selection rules for this novel reversal mechanism. Our analysis reveals that for spin wave excitation the concept of a critical velocity as the switching condition has to be modified., Comment: Minor corrections and polishing of previous version

Published

2010

44. Local breaking of the spin-orbit interaction: the microscopic origin of exchange bias in Co/FeMn

Author

Brück, Sebastian, Audehm, Patrick, Schütz, Gisela, and Goering, Eberhard

Subjects

Condensed Matter - Materials Science

Abstract

Modern magnetic thin film devices owe their success in large part to effects emerging from interlayer coupling and exchange interaction at interfaces. A prominent example is exchange bias (EB), a magnetic coupling phenomenon found in ferromagnet (F)/antiferromagnet (AF) systems. Uncompensated pinned moments in the AF couple to the F via the interface causing an additional unidirectional anisotropy. As a result, the hysteresis of the F is shifted. The existence of such pinned moments is nowadays accepted although their physical nature and origin is still unknown. Here we present a thorough spectroscopic investigation based on X-ray magnetic circular dichroism which does for the first time provide direct information about the physics of pinned magnetic moments. Our data clearly shows that the orbital magnetic moment, which is usually widely quenched in transition metal systems, is the driving force behind exchange bias in Co/FeMn.

Published

2009

45. Direct Observation of Propagating Spin Waves in the 2D van der Waals Ferromagnet Fe5 GeTe2

Author

Schulz, Frank, primary, Litzius, Kai, additional, Powalla, Lukas, additional, Birch, Max T., additional, Gallardo, Rodolfo A., additional, Satheesh, Sayooj, additional, Weigand, Markus, additional, Scholz, Tanja, additional, Lotsch, Bettina V., additional, Schütz, Gisela, additional, Burghard, Marko, additional, and Wintz, Sebastian, additional

Published

2023

46. Vortex core switching by coherent excitation with single in-plane magnetic field pulses

Author

Weigand, Markus, Van Waeyenberge, Bartel, Vansteenkiste, Arne, Curcic, Michael, Sackmann, Vitalij, Stoll, Hermann, Tyliszczak, Tolek, Kaznatcheev, Konstantine, Bertwistle, Drew, Woltersdorf, Georg, Back, Christian H., and Schütz, Gisela

Subjects

Condensed Matter - Other Condensed Matter

Abstract

The bistability of the core magnetization of nano-scaled magnets with a magnetic vortex configuration has great potential for data storage applications. To exploit this, reliable switching between the two possible states is needed. Time resolved x-ray microscopy was used to study the response of the vortex core to excitation pulses at sub-ns timescales and image the vortex core switching. A reliable switching process by coherent excitation with leading and trailing edges of in-plane magnetic field pulses was found and compared with micromagnetic simulations., Comment: 4 pages, 3 figures

Published

2008

47. Emission and propagation of 1D and 2D spin waves with nanoscale wavelengths in anisotropic spin textures

Author

Sluka, Volker, Schneider, Tobias, Gallardo, Rodolfo A., Kákay, Attila, Weigand, Markus, Warnatz, Tobias, Mattheis, Roland, Roldán-Molina, Alejandro, Landeros, Pedro, Tiberkevich, Vasil, Slavin, Andrei, Schütz, Gisela, Erbe, Artur, Deac, Alina, Lindner, Jürgen, Raabe, Jörg, Fassbender, Jürgen, and Wintz, Sebastian

Published

2019

48. Voltage X-Ray Reflectometry: A Method to Study Electric-Field-Induced Changes in Interfacial Electronic Structures

Author

Ilse, Sven Erik, primary, Schütz, Gisela, additional, and Goering, Eberhard, additional

Published

2023

49. Smooth and rapid microwave synthesis of MIL-53(Fe) including superparamagnetic [formula omitted] nanoparticles

Author

Wengert, Simon, Albrecht, Joachim, Ruoss, Stephen, Stahl, Claudia, Schütz, Gisela, and Schäfer, Ronald

Published

2017

50. Single shot acquisition of spatially resolved spin wave dispersion relations using X-ray microscopy

Author

Träger, Nick, Groß, Felix, Förster, Johannes, Baumgaertl, Korbinian, Stoll, Hermann, Weigand, Markus, Schütz, Gisela, Grundler, Dirk, and Gräfe, Joachim

Published

2020