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1. Time-Resolved Imaging Reveals Transiently Chaotic Spin-Orbit-Torque-Driven Dynamics Under Controlled Conditions

Author

Kern, Lisa-Marie, Litzius, Kai, Deinhart, Victor, Schneider, Michael, Klose, Christopher, Gerlinger, Kathinka, Battistelli, Riccardo, Engel, Dieter, Günther, Christian M., Huang, Meng-Jie, Höflich, Katja, Büttner, Felix, Eisebitt, Stefan, and Pfau, Bastian

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

Spin-orbit torques (SOTs) act as efficient drivers for nanoscale magnetic systems, such as in magnetic tunnel junctions, nano-oscillators and racetrack geometries. In particular, in combination with materials exhibiting high Dzyaloshinskii--Moriya interaction, SOTs are considered to result in well-controlled deterministic magnetisation dynamics and are, therefore, used as robust drives to move and create magnetic skyrmions. In contrast to these expectations, we here find unpredictable, transiently chaotic dynamics induced by SOT at an artificial anisotropy-engineered defect in a magnetic racetrack. Based on these controlled conditions, we directly observe the nanoscale dynamics with holography-based, time-resolved x-ray imaging. In concert with micromagnetic simulations, we disclose a regime of violent picosecond fluctuations, including topological instabilities that, remarkably, result in deterministic final configurations. In addition, our images expose previously unseen skyrmion shedding and highlight the potential of transiently chaotic pathways for topological switching. Our approach offers new perspectives for the investigation and application of highly non-linear SOT dynamics in spintronics materials.

Published
2024

2. Coherent x-ray magnetic imaging with 5 nm resolution

Author

Battistelli, Riccardo, Metternich, Daniel, Schneider, Michael, Kern, Lisa-Marie, Litzius, Kai, Fuchs, Josefin, Klose, Christopher, Gerlinger, Kathinka, Bagschik, Kai, Günther, Christian M., Engel, Dieter, Ropers, Claus, Eisebitt, Stefan, Pfau, Bastian, Büttner, Felix, and Zayko, Sergey

Subjects
Condensed Matter - Materials Science
Abstract

Soft x-ray microscopy plays an important role in modern spintronics. However, the achievable resolution of most x-ray magnetic imaging experiments is above 10 nm, limiting access to fundamental and technologically relevant length scales. Here, we demonstrate x-ray magnetic microscopy with 5 nm resolution by combining holography-assisted coherent diffractive imaging with heterodyne amplification of the weak magnetic signal. The gain in resolution and contrast allows direct access to key magnetic properties, including domain wall profiles and the position of pinning sites. The ability to detect and map such properties with photons opens new horizons for element-specific, time-resolved, and in-operando research on magnetic materials and beyond., Comment: 12 pages, 12 figures

Published
2023

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
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4. Tailoring Optical Excitation to Control Magnetic Skyrmion Nucleation

Author

Kern, Lisa-Marie, Pfau, Bastian, Schneider, Michael, Gerlinger, Kathinka, Deinhart, Victor, Wittrock, Steffen, Sidiropoulos, Themistoklis, Engel, Dieter, Will, Ingo, Günther, Christian M., Litzius, Kai, Wintz, Sebastian, Weigand, Markus, Büttner, Felix, and Eisebitt, Stefan

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

In ferromagnetic multilayers, a single laser pulse with a fluence above an optical nucleation threshold can create magnetic skyrmions, which are randomly distributed over the area of the laser spot. However, in order to study the dynamics of skyrmions and for their application in future data technology, a controllable localization of the skyrmion nucleation sites is crucial. Here, it is demonstrated that patterned reflective masks behind a thin magnetic film can be designed to locally tailor the optical excitation amplitudes reached, leading to spatially controlled skyrmion nucleation on the nanometer scale. Using x-ray microscopy, the influence of nanopatterned back-side aluminum masks on the optical excitation is studied in two sample geometries with varying layer sequence of substrate and magnetic Co/Pt multilayer. Surprisingly, the masks' effect on suppressing or enhancing skymion nucleation reverses when changing this sequence. Moreover, optical near-field enhancements additionally affect the spatial arrangement of the nucleated skyrmions. Simulations of the spatial modulation of the laser excitation, and the following heat transfer across the interfaces in the two sample geometries are employed to explain these observations. The results demonstrate a reliable approach to add nanometer-scale spatial control to optically induced magnetization processes on ultrafast timescales.

Published
2022
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5. Computing and Memory Technologies based on Magnetic Skyrmions

Author

Vakili, Hamed, Zhou, Wei, Ma, Chung T, Morshed, Md Golam, Sakib, Mohammad Nazmus, Hartnett, Tim, Xu, Jun-Wen, Ganguly, Samiran, Litzius, Kai, Quessab, Yassine, Balachandran, Prasanna, Stan, Mircea, Poon, S J, Kent, Andrew D., Beach, Geoffrey, and Ghosh, Avik W.

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

Solitonic magnetic excitations such as domain walls and, specifically, skyrmionics enable the possibility of compact, high density, ultrafast,all-electronic, low-energy devices, which is the basis for the emerging area of skyrmionics. The topological winding of skyrmion spins affects their overall lifetime, energetics and dynamical behavior. In this review, we discuss skyrmionics in the context of the present day solid state memory landscape, and show how their size, stability and mobility can be controlled by material engineering, as well as how they can be nucleated and detected. Ferrimagnetsnear their compensation points are important candidates for this application, leading to detailed exploration of amorphous CoGd as well as the study of emergent materials such as Mn$_4$N and Inverse Heusler alloys. Along with material properties, geometrical parameters such as film thickness, defect density and notches can be used to tune skyrmion properties, such as their size and stability. Topology, however, can be a double-edged sword, especially for isolated metastable skyrmions, as it brings stability at the cost of additional damping and deflective Magnus forces compared to domain walls. Skyrmion deformation in response to forces also makes them intrinsically slower than domain walls. We explore potential analog applications of skyrmions, including temporal memory at low density, and decorrelator for stochastic computing at a higher density that capitalizes on their interactions. We summarize the main challenges to achieve a skyrmionics technology, including maintaining positional stability with very high accuracy, electrical readout, especially for small ferrimagnetic skyrmions, deterministic nucleation and annihilation, and overall integration with digital circuits with the associated circuit overhead., Comment: 41 pages, 34 figure, review

Published
2021
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6. Anisotropic skyrmion diffusion controlled by field-induced symmetry breaking

Author

Kerber, Nico, Weißenhofer, Markus, Raab, Klaus, Litzius, Kai, Zázvorka, Jakub, Nowak, Ulrich, and Kläui, Mathias

Subjects
Condensed Matter - Materials Science
Abstract

Diffusion of particles has wide repercussions ranging from particle-based soft matter systems to solid state systems with particular electronic properties. Recently, in the field of magnetism, diffusion of magnetic skyrmions, topologically stabilized quasi-particles, has been demonstrated. Here we show that by applying a magnetic in-plane field and therefore breaking the symmetry of the system, the skyrmion diffusion becomes anisotropic with faster diffusion parallel to the field axis and slower diffusion perpendicular to it. We furthermore show that the absolute value of the applied field controls the absolute values of the diffusion coefficients so that one can thereby uniquely tune both the orientation of the diffusion and its strength. Based on the stochastic Thiele equation, we can explain the observed anisotropic diffusion as a result of the elliptical deformation of the skyrmions by the application of the in-plane field., Comment: 13 pages, 5 figures

Published
2020
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7. Skyrmion Lattice Phases in Thin Film Multilayer

Author

Zázvorka, Jakub, Dittrich, Florian, Ge, Yuquing, Kerber, Nico, Raab, Klaus, Winkler, Thomas, Litzius, Kai, Veis, Martin, Virnau, Peter, and Kläui, Mathias

Subjects
Condensed Matter - Materials Science
Abstract

Phases of matter are ubiquitous with everyday examples including solids and liquids. In reduced dimensions, particular phases, such as the two-dimensional (2D) hexatic phase and corresponding phase transitions occur. A particularly exciting example of 2D ordered systems are skyrmion lattices, where in contrast to previously studied 2D colloid systems, the skyrmion size and density can be tuned by temperature and magnetic field. This allows us to drive the system from a liquid phase to a hexatic phase as deduced from the analysis of the hexagonal order. Using coarse-grained molecular dynamics simulations of soft disks, we determine the skyrmion interaction potentials and we find that the simulations are able to reproduce the full two-dimensional phase behavior. This shows that not only the static behavior of skyrmions is qualitatively well described in terms of a simple two-dimensional model system but skyrmion lattices are versatile and tunable two-dimensional model systems that allow for studying phases and phase transitions in reduced dimensions., Comment: Corrected Acknowledgements

Published
2020
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8. Faster chiral versus collinear magnetic order recovery after optical excitation revealed by femtosecond XUV scattering

Author

Kerber, Nico, Ksenzov, Dmitriy, Freimuth, Frank, Capotondi, Flavio, Pedersoli, Emanuele, Lopez-Quintas, Ignacio, Seng, Boris, Cramer, Joel, Litzius, Kai, Lacour, Daniel, Zabel, Hartmut, Mokrousov, Yuriy, Kläui, Mathias, and Gutt, Christian

Subjects
Condensed Matter - Materials Science
Abstract

While chiral spin structures stabilized by Dzyaloshinskii-Moriya interaction (DMI) are candidates as novel information carriers, their dynamics on the fs-ps timescale is little known. Since with the bulk Heisenberg exchange and the interfacial DMI two distinct exchange mechanisms are at play, the ultra-fast dynamics of the chiral order needs to be ascertained and compared to the dynamics of the conventional collinear order. Using an XUV free-electron laser we determine the fs-ps temporal evolution of the chiral order in domain walls in a magnetic thin film sample by an IR pump - X-ray magnetic scattering probe experiment. Upon demagnetisation we observe that the dichroic (CL-CR) signal connected with the chiral order correlator $m_z m_x$ in the domain walls recovers significantly faster than the (CL+CR) sum signal representing the average collinear domain magnetisation $m_z^2 + m_x^2$. We explore possible explanations based on spin structure dynamics and reduced transversal magnetisation fluctuations inside the domain walls and find that the latter can explain the experimental data leading to different dynamics for collinear magnetic order and chiral magnetic order., Comment: 28 pages, 14 figures

Published
2020
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10. Scaling of intrinsic domain wall magneto-resistance with confinement in electromigrated nanocontacts

Author

Reeve, Robert M., Loescher, André, Kazemi, Hamidreza, Dupé, Bertrand, Winkler, Thomas, Schönke, Daniel, Miao, Jun, Litzius, Kai, Sedlmayr, Nicholas, Schneider, Imke, Sinova, Jairo, Eggert, Sebastian, and Kläui, Mathias

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this work we study the evolution of intrinsic domain wall magnetoresistance (DWMR) with domain wall confinement. Clean permalloy notched half-ring nanocontacts are fabricated using a special ultra-high vacuum electromigration procedure to tailor the size of the wire in-situ and through the resulting domain wall confinement we tailor the domain wall width from a few tens of nm down to a few nm. Through measurements of the dependence of the resistance with respect to the applied field direction we extract the contribution of a single domain wall to the MR of the device, as a function of the domain wall width in the confining potential at the notch. In this size range, an intrinsic positive MR is found, which dominates over anisotropic MR, as confirmed by comparison to micromagnetic simulations. Moreover, the MR is found to scale monotonically with the size of the domain wall, $\delta_{DW}$, as 1/$\delta_{DW}^b$, with $b=2.31\pm 0.39 $. The experimental result is supported by quantum-mechanical transport simulations based on ab-initio density functional theory calculations.

Published
2018
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11. Thermal skyrmion diffusion applied in probabilistic computing

Author

Zázvorka, Jakub, Jakobs, Florian, Heinze, Daniel, Keil, Niklas, Kromin, Sascha, Jaiswal, Samridh, Litzius, Kai, Jakob, Gerhard, Virnau, Peter, Pinna, Daniele, Everschor-Sitte, Karin, Donges, Andreas, Nowak, Ulrich, and Kläui, Mathias

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Computational Physics
Abstract

Thermally activated processes are key to understanding the dynamics of physical systems. Thermal diffusion of (quasi-)particles for instance not only yields information on transport and dissipation processes but is also an exponentially sensitive tool to reveal emergent system properties and enable novel applications such as probabilistic computing. Here we probe the thermal dynamics of topologically stabilized magnetic skyrmion quasi-particles. We demonstrate in a specially tailored low pinning multilayer material system pure skyrmion diffusion that dominates the dynamics. Finally, we analyse the applicability to probabilistic computing by constructing a device, which uses the thermally excited skyrmion dynamics to reshuffle a signal. Such a skyrmion reshuffler is the key missing component for probabilistic computing and by evaluating its performance, we demonstrate the functionality of our device with high fidelity thus enabling probabilistic computing.

Published
2018
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12. Tutorial: Simulating modern magnetic material systems in mumax3.

Author

Joos, Jonas J., Bassirian, Pedram, Gypens, Pieter, Mulkers, Jeroen, Litzius, Kai, Van Waeyenberge, Bartel, and Leliaert, Jonathan

Subjects
MAGNETIC materials, SPIN-orbit interactions, SPINTRONICS, TORQUE, MAGNETIZATION
Abstract

This Tutorial article focuses on magnetic phenomena and material systems that have gained significant importance since the original development of mumax3, but are challenging to simulate for users who rely solely on the originally provided examples. Alongside the physical background, we provide hands-on examples of advanced magnetic systems, including detailed explanations of complete mumax3 input files (13 in total, often showing different ways to achieve things), and highlighting potential pitfalls where applicable. Specifically, we explore two approaches to incorporate spin–orbit torques in mumax simulations, considering the trade-off between versatility and speed. We also examine complex multilayer material stacks, including synthetic antiferromagnets, demonstrating different implementation methods that again vary in speed, versatility, and realism. A key criterion for selecting the optimal simulation strategy is its suitability for modeling systems where the magnetization varies significantly in the third dimension. The material covered in this Tutorial paper includes content developed for the mumax3 workshop presented during the summer of 2020 within the context of the IEEE online spintronics seminar, along with additional new topics. Throughout the explanations, we ensure broad applicability beyond specific examples. [ABSTRACT FROM AUTHOR]

Published
2023
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13. Multiscale simulations of topological transformations in magnetic Skyrmions

Author

De Lucia, Andrea, Litzius, Kai, Krüger, Benjamin, Tretiakov, Oleg A., and Kläui, Mathias

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

Magnetic Skyrmions belong to the most interesting spin structures for the development of future information technology as they have been predicted to be topologically protected. To quantify their stability, we use an innovative multiscale approach to simulating spin dynamics based on the Landau-Lifshitz-Gilbert equation. The multiscale approach overcomes the micromagnetic limitations that have hindered realistic studies using conventional techniques. We first demonstrate how the stability of a Skyrmion is influenced by the refinement of the computational mesh and reveal that conventionally employed traditional micromagnetic simulations are inadequate for this task. Furthermore, we determine the stability quantitatively using our multiscale approach. As a key operation for devices, the process of annihilating a Skyrmion by exciting it with a spin polarized current pulse is analyzed, showing that Skyrmions can be reliably deleted by designing the pulse shape.

Published
2017
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14. A magnetic skyrmion as a non-linear resistive element - a potential building block for reservoir computing

Author

Prychynenko, Diana, Sitte, Matthias, Litzius, Kai, Krüger, Benjamin, Bourianoff, George, Kläui, Mathias, Sinova, Jairo, and Everschor-Sitte, Karin

Subjects
Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Other Condensed Matter, Condensed Matter - Strongly Correlated Electrons
Abstract

Inspired by the human brain, there is a strong effort to find alternative models of information processing capable of imitating the high energy efficiency of neuromorphic information processing. One possible realization of cognitive computing are reservoir computing networks. These networks are built out of non-linear resistive elements which are recursively connected. We propose that a skyrmion network embedded in frustrated magnetic films may provide a suitable physical implementation for reservoir computing applications. The significant key ingredient of such a network is a two-terminal device with non-linear voltage characteristics originating from single-layer magnetoresistive effects, like the anisotropic magnetoresistance or the recently discovered non-collinear magnetoresistance. The most basic element for a reservoir computing network built from "skyrmion fabrics" is a single skyrmion embedded in a ferromagnetic ribbon. In order to pave the way towards reservoir computing systems based on skyrmion fabrics, here we simulate and analyze i) the current flow through a single magnetic skyrmion due to the anisotropic magneto-resistive effect and ii) the combined physics of local pinning and the anisotropic magneto-resistive effect., Comment: 22 pages, 8 figures; author's name corrected

Published
2017
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15. 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

16. 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
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17. Observation of room temperature magnetic skyrmions and their current-driven dynamics in ultrathin Co films

Author

Woo, Seonghoon, Litzius, Kai, Krüger, Benjamin, Im, Mi-Young, Caretta, Lucas, Richter, Kornel, Mann, Maxwell, Krone, Andrea, Reeve, Robert, Weigand, Markus, Agrawal, Parnika, Fischer, Peter, Kläui, Mathias, and Beach, Geoffrey S. D.

Subjects
Condensed Matter - Materials Science
Abstract

Magnetic skyrmions are topologically-protected spin textures that exhibit fascinating physical behaviors and large potential in highly energy efficient spintronic device applications. The main obstacles so far are that skyrmions have been observed in only a few exotic materials and at low temperatures, and manipulation of individual skyrmions has not yet been achieved. Here, we report the observation of stable magnetic skyrmions at room temperature in ultrathin transition metal ferromagnets with magnetic transmission soft x-ray microscopy. We demonstrate the ability to generate stable skyrmion lattices and drive trains of individual skyrmions by short current pulses along a magnetic racetrack. Our findings provide experimental evidence of recent predictions and open the door to room-temperature skyrmion spintronics in robust thin-film heterostructures., Comment: 12 pages 3 figures

Published
2015
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19. Coherent x-ray magnetic imaging with 5 nm resolution

Author

Battistelli, Riccardo, primary, Metternich, Daniel, additional, Schneider, Michael, additional, Kern, Lisa-Marie, additional, Litzius, Kai, additional, Fuchs, Josefin, additional, Klose, Christopher, additional, Gerlinger, Kathinka, additional, Bagschik, Kai, additional, Günther, Christian M., additional, Engel, Dieter, additional, Ropers, Claus, additional, Eisebitt, Stefan, additional, Pfau, Bastian, additional, Büttner, Felix, additional, and Zayko, Sergey, additional

Published
2024
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20. 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
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21. Observation of room-temperature magnetic skyrmions and their current-driven dynamics in ultrathin metallic ferromagnets

Author

Woo, Seonghoon, Litzius, Kai, Krüger, Benjamin, Im, Mi-Young, Caretta, Lucas, Richter, Kornel, Mann, Maxwell, Krone, Andrea, Reeve, Robert M, Weigand, Markus, Agrawal, Parnika, Lemesh, Ivan, Mawass, Mohamad-Assaad, Fischer, Peter, Kläui, Mathias, and Beach, Geoffrey SD

Subjects
Quantum Physics, Physical Sciences, cond-mat.mtrl-sci, Nanoscience & Nanotechnology
Abstract

Magnetic skyrmions are topologically protected spin textures that exhibit fascinating physical behaviours and large potential in highly energy-efficient spintronic device applications. The main obstacles so far are that skyrmions have been observed in only a few exotic materials and at low temperatures, and fast current-driven motion of individual skyrmions has not yet been achieved. Here, we report the observation of stable magnetic skyrmions at room temperature in ultrathin transition metal ferromagnets with magnetic transmission soft X-ray microscopy. We demonstrate the ability to generate stable skyrmion lattices and drive trains of individual skyrmions by short current pulses along a magnetic racetrack at speeds exceeding 100 m s(-1) as required for applications. Our findings provide experimental evidence of recent predictions and open the door to room-temperature skyrmion spintronics in robust thin-film heterostructures.

Published
2016

22. 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
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24. Contributors

Author

Bonanno, Gabriele, primary, Büttner, Felix, additional, Carpentieri, Mario, additional, Chen, Xing, additional, Chubykalo-Fesenko, Oksana, additional, D’Aguì, Giuseppina, additional, Denisov, Konstantin, additional, Ezawa, Motohiko, additional, Fischer, Peter, additional, Hug, Hans J., additional, Kang, Wang, additional, Kläui, Mathias, additional, Legrand, William, additional, Lei, Na, additional, Leonov, Andrey O., additional, Li, Sai, additional, Litzius, Kai, additional, Liu, Xiaoxi, additional, Miltat, Jacques, additional, Pappas, Catherine, additional, Rohart, Stanislas, additional, Roy, Sujoy, additional, Rozhansky, Igor, additional, Sánchez-Tejerina, Luis, additional, Shen, Laichuan, additional, Thiaville, André, additional, Tomasello, Riccardo, additional, Tretiakov, Oleg A., additional, Woo, Seonghoon, additional, Xia, Jing, additional, Zhang, Xichao, additional, Zhang, Xueying, additional, Zhao, Weisheng, additional, Zhou, Yan, additional, Zhu, Daoqian, additional, and Zivieri, Roberto, additional

Published
2021
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27. Thermal skyrmion diffusion used in a reshuffler device

Author

Zázvorka, Jakub, Jakobs, Florian, Heinze, Daniel, Keil, Niklas, Kromin, Sascha, Jaiswal, Samridh, Litzius, Kai, Jakob, Gerhard, Virnau, Peter, Pinna, Daniele, Everschor-Sitte, Karin, Rózsa, Levente, Donges, Andreas, Nowak, Ulrich, and Kläui, Mathias

Published
2019
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28. Author Correction: Coherent correlation imaging for resolving fluctuating states of matter

Author

Klose, Christopher, primary, Büttner, Felix, additional, Hu, Wen, additional, Mazzoli, Claudio, additional, Litzius, Kai, additional, Battistelli, Riccardo, additional, Zayko, Sergey, additional, Lemesh, Ivan, additional, Bartell, Jason M., additional, Huang, Mantao, additional, Günther, Christian M., additional, Schneider, Michael, additional, Barbour, Andi, additional, Wilkins, Stuart B., additional, Beach, Geoffrey S. D., additional, Eisebitt, Stefan, additional, and Pfau, Bastian, additional

Published
2023
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29. Skyrmionics—Computing and memory technologies based on topological excitations in magnets.

Author

Vakili, Hamed, Zhou, Wei, Ma, Chung T., Poon, S. J., Morshed, Md Golam, Sakib, Mohammad Nazmus, Ganguly, Samiran, Stan, Mircea, Hartnett, Timothy Q., Balachandran, Prasanna, Xu, Jun-Wen, Quessab, Yassine, Kent, Andrew D., Litzius, Kai, Beach, Geoffrey S. D., and Ghosh, Avik W.

Subjects
MAGNETIC domain walls, HEUSLER alloys, MAGNETS, DIGITAL electronics, DOMAIN walls (Ferromagnetism), SKYRMIONS, SUPERCONDUCTING magnets, NOTCH effect
Abstract

Solitonic magnetic excitations such as domain walls and, specifically, skyrmionics enable the possibility of compact, high density, ultrafast, all-electronic, low-energy devices, which is the basis for the emerging area of skyrmionics. The topological winding of skyrmion spins affects their overall lifetime, energetics, and dynamical behavior. In this Perspective, we discuss skyrmionics in the context of the present-day solid-state memory landscape and show how their size, stability, and mobility can be controlled by material engineering, as well as how they can be nucleated and detected. Ferrimagnets near their compensation points are promising candidates for this application, leading to a detailed exploration of amorphous CoGd as well as the study of emergent materials such as Mn 4 N and inverse Heusler alloys. Along with material properties, geometrical parameters such as film thickness, defect density, and notches can be used to tune skyrmion properties, such as their size and stability. Topology, however, can be a double-edged sword, especially for isolated metastable skyrmions, as it brings stability at the cost of additional damping and deflective Magnus forces compared to domain walls. Skyrmion deformation in response to forces also makes them intrinsically slower than domain walls. We explore potential analog applications of skyrmions, including temporal memory at low density—one skyrmion per racetrack—that capitalizes on their near ballistic current–velocity relation to map temporal data to spatial data and decorrelators for stochastic computing at a higher density that capitalizes on their interactions. We summarize the main challenges of achieving a skyrmionics technology, including maintaining positional stability with very high accuracy and electrical readout, especially for small ferrimagnetic skyrmions, deterministic nucleation, and annihilation and overall integration with digital circuits with the associated circuit overhead. [ABSTRACT FROM AUTHOR]

Published
2021
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31. Seeding and Emergence of Composite Skyrmions in a van der Waals Magnet

Author

Powalla, Lukas, primary, Birch, Max T., additional, Litzius, Kai, additional, Wintz, Sebastian, additional, Yasin, Fehmi S., additional, Turnbull, Luke A., additional, Schulz, Frank, additional, Mayoh, Daniel A., additional, Balakrishnan, Geetha, additional, Weigand, Markus, additional, Yu, Xiuzhen, additional, Kern, Klaus, additional, Schütz, Gisela, additional, and Burghard, Marko, additional

Published
2023
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32. Role of substrate clamping on anisotropy and domain structure in the canted antiferromagnet α-Fe2O3

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
Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences
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 $α$-Fe$_2$O$_3$. We find that the internal destressing fields driving the formation of domains do not follow the crystal symmetry of $α$-Fe$_2$O$_3$, but fluctuate due to substrate clamping. This leads to an overall isotropic distribution of the Néel order with locally varying effective anisotropy in antiferromagnetic thin films. Furthermore, we show that the weak ferromagnetic nature of $α$-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., 9 pages, 5 figures

Published
2022

33. Role of substrate clamping on anisotropy and domain structure in the canted antiferromagnet α−Fe2O3

Author

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

Published
2022
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35. Application concepts for ultrafast laser-induced skyrmion creation and annihilation

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Gerlinger, Kathinka, Pfau, Bastian, Büttner, Felix, Schneider, Michael, Kern, Lisa-Marie, Fuchs, Josefin, Engel, Dieter, Günther, Christian M, Huang, Mantao, Lemesh, Ivan, Caretta, Lucas, Churikova, Alexandra, Hessing, Piet, Klose, Christopher, Strüber, Christian, Schmising, Clemens von Korff, Huang, Siying, Wittmann, Angela, Litzius, Kai, Metternich, Daniel, Battistelli, Riccardo, Bagschik, Kai, Sadovnikov, Alexandr, Beach, Geoffrey SD, Eisebitt, Stefan, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Gerlinger, Kathinka, Pfau, Bastian, Büttner, Felix, Schneider, Michael, Kern, Lisa-Marie, Fuchs, Josefin, Engel, Dieter, Günther, Christian M, Huang, Mantao, Lemesh, Ivan, Caretta, Lucas, Churikova, Alexandra, Hessing, Piet, Klose, Christopher, Strüber, Christian, Schmising, Clemens von Korff, Huang, Siying, Wittmann, Angela, Litzius, Kai, Metternich, Daniel, Battistelli, Riccardo, Bagschik, Kai, Sadovnikov, Alexandr, Beach, Geoffrey SD, and Eisebitt, Stefan

Published
2022

36. Skyrmionics—Computing and memory technologies based on topological excitations in magnets

Author

MIT Materials Research Laboratory, Vakili, Hamed, Xu, Jun-Wen, Zhou, Wei, Sakib, Mohammad Nazmus, Morshed, Md Golam, Hartnett, Timothy, Quessab, Yassine, Litzius, Kai, Ma, Chung T, Ganguly, Samiran, Stan, Mircea R, Balachandran, Prasanna V, Beach, Geoffrey SD, Poon, S Joseph, Kent, Andrew D, Ghosh, Avik W, MIT Materials Research Laboratory, Vakili, Hamed, Xu, Jun-Wen, Zhou, Wei, Sakib, Mohammad Nazmus, Morshed, Md Golam, Hartnett, Timothy, Quessab, Yassine, Litzius, Kai, Ma, Chung T, Ganguly, Samiran, Stan, Mircea R, Balachandran, Prasanna V, Beach, Geoffrey SD, Poon, S Joseph, Kent, Andrew D, and Ghosh, Avik W

Published
2022

37. Skyrmionics—Computing and memory technologies based on topological excitations in magnets

Author

Vakili, Hamed, Xu, Jun-Wen, Zhou, Wei, Sakib, Mohammad Nazmus, Morshed, Md Golam, Hartnett, Timothy, Quessab, Yassine, Litzius, Kai, Ma, Chung T, Ganguly, Samiran, Stan, Mircea R, Balachandran, Prasanna V, Beach, Geoffrey SD, Poon, S Joseph, Kent, Andrew D, Ghosh, Avik W, Vakili, Hamed, Xu, Jun-Wen, Zhou, Wei, Sakib, Mohammad Nazmus, Morshed, Md Golam, Hartnett, Timothy, Quessab, Yassine, Litzius, Kai, Ma, Chung T, Ganguly, Samiran, Stan, Mircea R, Balachandran, Prasanna V, Beach, Geoffrey SD, Poon, S Joseph, Kent, Andrew D, and Ghosh, Avik W

Published
2022

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

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, 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, Beach, Geoffrey S. D., Massachusetts Institute of Technology. Department of Materials Science and Engineering, 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 S. D.

Published
2022

39. Magnetic Properties and Growth‐Induced Anisotropy in Yttrium Thulium Iron Garnet Thin Films

Author

Rosenberg, Ethan R., Litzius, Kai, Shaw, Justin M., Riley, Grant A., Beach, Geoffrey S. D., Nembach, Hans T., Ross, Caroline A., Rosenberg, Ethan R., Litzius, Kai, Shaw, Justin M., Riley, Grant A., Beach, Geoffrey S. D., Nembach, Hans T., and Ross, Caroline A.

Abstract

Rare-earth iron garnets (REIG) have recently become the materials platform of choice for spintronic studies on ferrimagnetic insulators. However, thus far the materials studied have mainly been REIG with a single rare earth species such as thulium, yttrium, or terbium iron garnets. In this study, magnetometry, ferromagnetic resonance, and magneto-optical Kerr effect imaging is used to explore the continuous variation of magnetic properties as a function of composition for YxTm3−x iron garnet (YxTm3−xIG) thin films grown by pulsed laser deposition on gadolinium gallium garnet substrates. It is reported that the tunability of the magnetic anisotropy energy, with full control achieved over the type of anisotropy (from perpendicular, to isotropic, to an in-plane easy axis) on the same substrate. In addition, a nonmonotonic composition-dependent anisotropy term is reported, which is ascribed to growth-induced anisotropy similar to what is reported in garnet thin films grown by liquid-phase epitaxy. Ferromagnetic resonance shows linear variation of the damping and the g-factor across the composition range, consistent with prior theoretical work. Domain imaging reveals differences in reversal modes, remanant states, and domain sizes in YxTm3−x iron-garnet thin films as a function of anisotropy.

Published
2022

41. Skyrmion States in Disk Geometry

Author

Winkler, Thomas Brian, primary, Litzius, Kai, additional, de Lucia, Andrea, additional, Weißenhofer, Markus, additional, Fangohr, Hans, additional, and Kläui, Mathias, additional

Published
2021
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43. Publisher’s Note: “Skyrmionics—Computing and memory technologies based on topological excitations in magnets” [J. Appl. Phys. 130, 070908 (2021)]

Author

Vakili, Hamed, primary, Xu, Jun-Wen, additional, Zhou, Wei, additional, Sakib, Mohammad Nazmus, additional, Morshed, Md Golam, additional, Hartnett, Timothy, additional, Quessab, Yassine, additional, Litzius, Kai, additional, Ma, Chung T., additional, Ganguly, Samiran, additional, Stan, Mircea R., additional, Balachandran, Prasanna V., additional, Beach, Geoffrey S. D., additional, Joseph Poon, S., additional, Kent, Andrew D., additional, and Ghosh, Avik W., additional

Published
2021
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45. Application concepts for ultrafast laser-induced skyrmion creation and annihilation

Author

Gerlinger, Kathinka, primary, Pfau, Bastian, additional, Büttner, Felix, additional, Schneider, Michael, additional, Kern, Lisa-Marie, additional, Fuchs, Josefin, additional, Engel, Dieter, additional, Günther, Christian M., additional, Huang, Mantao, additional, Lemesh, Ivan, additional, Caretta, Lucas, additional, Churikova, Alexandra, additional, Hessing, Piet, additional, Klose, Christopher, additional, Strüber, Christian, additional, Schmising, Clemens von Korff, additional, Huang, Siying, additional, Wittmann, Angela, additional, Litzius, Kai, additional, Metternich, Daniel, additional, Battistelli, Riccardo, additional, Bagschik, Kai, additional, Sadovnikov, Alexandr, additional, Beach, Geoffrey S. D., additional, and Eisebitt, Stefan, additional

Published
2021
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47. Chiral versus collinear magnetic order dynamics: faster chiral recovery after optical excitation revealed by femtosecond XUV scattering

Author

Kerber, Nico, Ksenzov, Dmitriy, Freimuth, Frank, Capotondi, Flavio, Pedersoli, Emanuele, Lopez-Quintas, Ignacio, Seng, Boris, Cramer, Joel, Litzius, Kai, Lacour, Daniel, Zabel, Hartmut, Mokrousov, Yuriy, Kläui, Mathias, Gutt, Christian, Elettra Sincrotrone Trieste, Institut Jean Lamour (IJL), Université de Lorraine (UL)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Institut für Physik, Johannes Gutenberg-Universität Mainz, Department Physik, Universität Siegen, and Lacour, Daniel

Subjects
[PHYS]Physics [physics], [PHYS.COND]Physics [physics]/Condensed Matter [cond-mat], [PHYS.COND] Physics [physics]/Condensed Matter [cond-mat], [PHYS] Physics [physics]
Abstract

While chiral spin structures stabilized by Dzyaloshinskii-Moriya interaction (DMI) are candidates as novel information carriers, their dynamics on the fs-ps timescale is little known. Since with the bulk Heisenberg exchange and the interfacial DMI two distinct exchange mechanisms are at play, the ultra-fast dynamics of the chiral order needs to be ascertained and compared to the dynamics of the conventional collinear order. Using an XUV free-electron laser we determine the fs-ps temporal evolution of the chiral order in domain walls in a magnetic thin film sample by an IR pump-X-ray magnetic scattering probe experiment. Upon demagnetisation we observe that the dichroic (CL-CR) signal from the chiral order in the domain walls recovers significantly faster than the (CL+CR) sum signal from the average collinear domain magnetisation. We explore possible explanations based on spin structure dynamics and reduced transversal magnetisation fluctuations inside the domain walls and find that the latter can explain the experimental data leading to distinctly different dynamics for collinear magnetic order and chiral magnetic order.

Published
2020

48. Thermal nucleation and high-resolution imaging of submicrometer magnetic bubbles in thin thulium iron garnet films with perpendicular anisotropy

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Büttner, Felix, Mawass, Mohamad A., Bauer, Jackson, Rosenberg, Ethan Raphael, Caretta, Lucas Marcelo, Avci, Can Onur, Gräfe, Joachim, Finizio, Simone, Vaz, C. A. F., Novakovic, Nina, Weigand, Markus, Litzius, Kai, Förster, Johannes, Träger, Nick, Groß, Felix, Suzuki, Daniel, Huang, Mantao, Bartell, Jason M, Kronast, Florian, Raabe, Jörg, Schütz, Gisela, Ross, Caroline A., Beach, Geoffrey Stephen, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Büttner, Felix, Mawass, Mohamad A., Bauer, Jackson, Rosenberg, Ethan Raphael, Caretta, Lucas Marcelo, Avci, Can Onur, Gräfe, Joachim, Finizio, Simone, Vaz, C. A. F., Novakovic, Nina, Weigand, Markus, Litzius, Kai, Förster, Johannes, Träger, Nick, Groß, Felix, Suzuki, Daniel, Huang, Mantao, Bartell, Jason M, Kronast, Florian, Raabe, Jörg, Schütz, Gisela, Ross, Caroline A., and Beach, Geoffrey Stephen

Abstract

Ferrimagnetic iron garnets are promising materials for spintronics applications, characterized by ultralow damping and zero current shunting. It has recently been found that few nm-thick garnet films interfaced with a heavy metal can also exhibit sizable interfacial spin-orbit interactions, leading to the emergence, and efficient electrical control, of one-dimensional chiral domain walls. Two-dimensional bubbles, by contrast, have so far only been confirmed in micrometer-thick films. Here, we show by high resolution scanning transmission x-ray microscopy and photoemission electron microscopy that submicrometer bubbles can be nucleated and stabilized in ∼25-nm-thick thulium iron garnet films via short heat pulses generated by electric current in an adjacent Pt strip, or by ultrafast laser illumination. We also find that quasistatic processes do not lead to the formation of a bubble state, suggesting that the thermodynamic path to reaching that state requires transient dynamics. X-ray imaging reveals that the bubbles have Bloch-type walls with random chirality and topology, indicating negligible chiral interactions at the garnet film thickness studied here. The robustness of thermal nucleation and the feasibility demonstrated here to image garnet-based devices by x-rays both in transmission geometry and with sensitivity to the domain wall chirality are critical steps to enabling the study of small spin textures and dynamics in perpendicularly magnetized thin-film garnets., US Defense Advanced Research Projects Agency (DARPA) under Project No. HR0011834375, NSF Grant No. DMR1808190

Published
2020

49. Faster chiral versus collinear magnetic order recovery after optical excitation revealed by femtosecond XUV scattering

Author

Kerber, Nico, primary, Ksenzov, Dmitriy, additional, Freimuth, Frank, additional, Capotondi, Flavio, additional, Pedersoli, Emanuele, additional, Lopez-Quintas, Ignacio, additional, Seng, Boris, additional, Cramer, Joel, additional, Litzius, Kai, additional, Lacour, Daniel, additional, Zabel, Hartmut, additional, Mokrousov, Yuriy, additional, Kläui, Mathias, additional, and Gutt, Christian, additional

Published
2020
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50. Skyrmion Lattice Phases in Thin Film Multilayer

Author

Zázvorka, Jakub, primary, Dittrich, Florian, additional, Ge, Yuqing, additional, Kerber, Nico, additional, Raab, Klaus, additional, Winkler, Thomas, additional, Litzius, Kai, additional, Veis, Martin, additional, Virnau, Peter, additional, and Kläui, Mathias, additional

Published
2020
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