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175 results on '"Gomonay, O."'

1. Probing nonlinear spin dynamics in canted easy-plane antiferromagnets using spin-rectification effects

Author

Kanj, A. El, Mantion, S., Boventer, I., Bortolotti, P., Cros, V., Anane, A., Gomonay, O., and Lebrun, R.

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

We investigate spin-rectification phenomena in canted antiferromagnets, closely connected to the family of altermagnetic materials. Our results show that excitation efficiency is significantly enhanced by the Dzyaloshinskii-Moriya interaction. Antiferromagnetic dynamics can be detected through spin-Hall magnetoresistance and bolometric effects, with an efficiency reaching up to mV/W. The rectified voltage shape is influenced by both the symmetry of the exciting torques, detection mechanisms (continuous spin-pumping and spin-Hall magnetoresistance), and the antiferromagnetic crystalline axis. Under high pumping power, we observe a saturation effect related to Suhl-like spin-wave instabilities and a nonlinear redshift of the antiferromagnetic resonance. These findings open new avenues for studying nonlinear dynamics in antiferromagnetic and altermagnetic spintronic devices.

Published
2024

2. Structure, control, and dynamics of altermagnetic textures

Author

Gomonay, O., Kravchuk, V. P., Jaeschke-Ubiergo, R., Yershov, K. V., Jungwirth, T., Šmejkal, L., Brink, J. van den, and Sinova, J.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present a phenomenological theory of altermagnets, that captures their unique magnetization dynamics and allows modelling magnetic textures in this new magnetic phase. Focusing on the prototypical d-wave altermagnets, e.g. RuO$_2$, we can explain intuitively the characteristic lifted degeneracy of their magnon spectra, by the emergence of an effective sublattice-dependent anisotropic spin stiffness arising naturally from the phenomenological theory. We show that as a consequence the altermagnetic domain walls, in contrast to antiferromagnets, have a finite gradient of the magnetization, with its strength and gradient direction connected to the altermagnetic anisotropy, even for 180$^\circ$ domain walls. This gradient generates a ponderomotive force in the domain wall in the presence of a strongly inhomogeneous external magnetic field, which may be achieved through magnetic force microscopy techniques. The motion of these altermagentic domain walls is also characterized by an anisotropic Walker breakdown, with much higher speed limits of propagation than ferromagnets but lower than antiferromagnets.

Published
2024
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3. Imprinting of Antiferromagnetic Vortex States in NiO-Fe Nanostructures

Author

Ślęzak, M., Wagner, T., Bharadwaj, V. K., Gomonay, O., Kozioł-Rachwał, A., Menteş, T. O., Locatelli, A., Zając, M., Wilgocka-Ślęzak, D., Dróżdż, P., and Ślęzak, T.

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

Magnetic vortices are topological spin structures frequently found in ferromagnets, yet novel to antiferromagnets. By combining experiment and theory, we demonstrate that in a nanostructured antiferromagnetic-ferromagnetic NiO(111)-Fe(110) bilayer, a magnetic vortex is naturally stabilized by magnetostatic interactions in the ferromagnet and is imprinted onto the adjacent antiferromagnet via interface exchange coupling. We use micromagnetic simulations to construct a corresponding phase diagram of the stability of the imprinted antiferromagnetic vortex state. Our in depth analysis reveals that the interplay between interface exchange coupling and the antiferromagnet magnetic anisotropy plays a crucial role in locally reorienting the N\'eel vector out-of-plane in the prototypical in-plane antiferromagnet NiO and thereby stabilizing the vortices in the antiferromagnet.

Published
2024

4. Antiferromagnetic insulatronics: spintronics in insulating 3d metal oxides with antiferromagnetic coupling

Author

Meer, H., Gomonay, O., Wittmann, A., and Kläui, M.

Subjects
Condensed Matter - Materials Science
Abstract

Antiferromagnetic transition metal oxides are an established and widely studied materials system in the context of spin-based electronics, commonly used as passive elements in exchange bias-based memory devices. Currently, major interest has resurged due to the recent observation of long-distance spin transport, current-induced switching, and THz emission. As a result, insulating transition metal oxides are now considered to be attractive candidates for active elements in novel spintronic devices. Here, we discuss some of the most promising materials systems and highlight recent advances in reading and writing antiferromagnetic ordering. This article aims to provide an overview of the current research and potential future directions in the field of antiferromagnetic insulatronics.

Published
2023
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5. Antiferromagnet-mediated interlayer exchange: hybridization versus proximity effect

Author

Polishchuk, D. M., Tykhonenko-Polishchuk, Yu. O., Lytvynenko, Ya. M., Rostas, A. M., Kuncser, V., Kravets, A. F., Tovstolytkin, A. I., Gomonay, O. V., and Korenivski, V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We investigate the interlayer coupling between two thin ferromagnetic (F) films mediated by an antiferromagnetic (AF) spacer in F*/AF/F trilayers and show how it transitions between different regimes on changing the AF thickness. Employing layer-selective Kerr magnetometry and ferromagnetic-resonance techniques in a complementary manner enables us to distinguish between three functionally distinct regimes of such ferromagnetic interlayer coupling. The F layers are found to be individually and independently exchange-biased for thick FeMn spacers - the first regime of no interlayer F-F* coupling. F-F* coupling appears on decreasing the FeMn thickness below 9 nm. In this second regime found in structures with 6.0-9.0 nm thick FeMn spacers, the interlayer coupling exists only in a finite temperature interval just below the effective N\'eel temperature of the spacer, which is due to magnon-mediated exchange through the thermally softened antiferromagnetic spacer, vanishing at lower temperatures. The third regime, with FeMn thinner than 4 nm, is characterized by a much stronger interlayer coupling in the entire temperature interval, which is attributed to a magnetic-proximity induced ferromagnetic exchange. These experimental results, spanning the key geometrical parameters and thermal regimes of the F*/AF/F nanostructure, complemented by a comprehensive theoretical analysis, should broaden the understanding of the interlayer exchange in magnetic multilayers and potentially be useful for applications in spin-thermionics., Comment: 14 pages, 9 figures

Published
2023
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6. Photocurrents, inverse Faraday effect and photospin Hall effect in Mn$_2$Au

Author

Merte, M., Freimuth, F., Go, D., Adamantopoulos, T., Lux, F. R., Plucinski, L., Gomonay, O., Blügel, S., and Mokrousov, Y.

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

Among antiferromagnetic materials, Mn$_2$Au is one of the most intensively studied, and it serves as a very popular platform for testing various ideas related to antiferromagnetic magnetotransport and dynamics. Since recently, this material has also attracted considerable interest in the context of optical properties and optically-driven antiferromagnetic switching. In this work, we use first principles methods to explore the physics of charge photocurrents, spin photocurrents and inverse Faraday effect in antiferromagnetic Mn$_2$Au. We predict the symmetry and magnitude of these effects, and speculate that they can be used for tracking the dynamics of staggered moments during switching. Our calculations reveal the emergence of large photocurrents of spin in collinear Mn$_2$Au, whose properties can be understood as a result of a non-linear optical version of spin Hall effect $-$ which we refer to as the $\textit{photospin Hall effect}$ encoded into the relation between the driving charge and resulting spin photocurrents. Moreover, we suggest that even a very small canting in Mn$_2$Au can give rise to colossal spin photocurrents which are $\textit{chiral}$ in flavor. We conclude that the combination of staggered magnetization with the structural and electronic properties of this material results in a unique blend of prominent photocurrents, which makes Mn$_2$Au a unique platform for advanced optospintronics applications.

Published
2023

7. Antiferromagnetic magnon spintronic based on non-reciprocal and non-degenerated ultra-fast spin-waves in the canted antiferromagnet {\alpha}-Fe2O3

Author

Kanj, A. El, Gomonay, O., Boventer, I., Bortolotti, P., Cros, V., Anane, A., and Lebrun, R.

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

Spin-waves in antiferromagnets hold the prospects for the development of faster, less power-hungry electronics, as well as promising physics based on spin-superfluids and coherent magnon-condensates. For both these perspectives, addressing electrically coherent antiferromagnetic spin-waves is of importance, a prerequisite that has so far been elusive, because unlike ferromagnets,antiferromagnets couple weakly to radiofrequency fields. Here, we demonstrate the detection of ultra-fast non-reciprocal spin-waves in the dipolar-exchange regime of a canted antiferromagnet using both inductive and spintronic transducers. Using time-of-flight spin-wave spectroscopy on hematite ({\alpha}-Fe2O3), we find that the magnon wave packets can propagate as fast as 20 km/s for reciprocal bulk spin-wave modes and up to 6 km/s for surface-spin waves propagating parallel to the antiferromagnetic Neel vector. We finally achieve efficient electrical detection of non-reciprocal spin-wave transport using non-local inverse spin-Hall effects. The electrical detection of coherent non-reciprocal antiferromagnetic spin waves paves the way for the development of antiferromagnetic and altermagnet-based magnonic devices.

Published
2023
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8. Emission of coherent THz magnons in an antiferromagnetic insulator triggered by ultrafast spin-phonon interactions

Author

Rongione, E., Gueckstock, O., Mattern, M., Gomonay, O., Meer, H., Schmitt, C., Ramos, R., Saitoh, E., Sinova, J., Jaffrès, H., Mičica, M., Mangeney, J., Goennenwein, S. T. B., Geprägs, S., Kampfrath, T., Kläui, M., Bargheer, M., Seifert, T. S., Dhillon, S., and Lebrun, R.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter, Physics - Optics
Abstract

Antiferromagnetic materials have been proposed as new types of narrowband THz spintronic devices owing to their ultrafast spin dynamics. Manipulating coherently their spin dynamics, however, remains a key challenge that is envisioned to be accomplished by spin-orbit torques or direct optical excitations. Here, we demonstrate the combined generation of broadband THz (incoherent) magnons and narrowband (coherent) magnons at 1 THz in low damping thin films of NiO/Pt. We evidence, experimentally and through modelling, two excitation processes of magnetization dynamics in NiO, an off-resonant instantaneous optical spin torque and a strain-wave-induced THz torque induced by ultrafast Pt excitation. Both phenomena lead to the emission of a THz signal through the inverse spin Hall effect in the adjacent heavy metal layer. We unravel the characteristic timescales of the two excitation processes found to be < 50 fs and > 300 fs, respectively, and thus open new routes towards the development of fast opto-spintronic devices based on antiferromagnetic materials.

Published
2022

9. Anisotropic long-range spin transport in canted antiferromagnetic orthoferrite YFeO$_3$

Author

Das, Shubhankar, Ross, A., Ma, X. X., Becker, S., Schmitt, C., van Duijn, F., Fuhrmann, F., Syskaki, M. -A., Ebels, U., Baltz, V., Barra, A. -L., Chen, H. Y., Jakob, G., Cao, S. X., Sinova, J., Gomonay, O., Lebrun, R., and Kläui, M.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In antiferromagnets, the efficient propagation of spin-waves has until now only been observed in the insulating antiferromagnet hematite, where circularly (or a superposition of pairs of linearly) polarized spin-waves propagate over long distances. Here, we report long-distance spin-transport in the antiferromagnetic orthoferrite YFeO$_3$, where a different transport mechanism is enabled by the combined presence of the Dzyaloshinskii-Moriya interaction and externally applied fields. The magnon decay length is shown to exceed hundreds of nano-meters, in line with resonance measurements that highlight the low magnetic damping. We observe a strong anisotropy in the magnon decay lengths that we can attribute to the role of the magnon group velocity in the propagation of spin-waves in antiferromagnets. This unique mode of transport identified in YFeO$_3$ opens up the possibility of a large and technologically relevant class of materials, i.e., canted antiferromagnets, for long-distance spin transport., Comment: Manuscript - 24 pages and 4 figures, Supplementary - 22 pages and 10 figures

Published
2021
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10. Photocurrents of charge and spin in single-layer Fe$_3$GeTe$_2$

Author

Merte, M., Freimuth, F., Adamantopoulos, T., Go, D., Saunderson, T. G., Kläui, M., Plucinski, L., Gomonay, O., Blügel, S., and Mokrousov, Y.

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

In the realm of two-dimensional materials magnetic and transport properties of a unique representative $-$ Fe$_3$GeTe$_2$ $-$ attract ever increasing attention. Here, we use a developed first-principles method for calculating laser-induced response to study the emergence of photo-induced currents of charge and spin in single-layer Fe$_3$GeTe$_2$, which are of second order in the electric field. We provide a symmetry analysis of the emergent photocurrents in the system finding it to be in excellent agreement with ab-initio calculations. We analyse the magnitude and behavior of the charge photocurrents with respect to disorder strength, frequency and band filling. Remarkably, not only do we find a large charge current response, but also predict that Fe$_3$GeTe$_2$ can serve as a source of significant laser-induced spin-currents, which makes this material as a promising platform for various applications in optospintronics.

Published
2021
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13. Magnetoelastic resonance as a probe for exchange springs at antiferromagnet-ferromagnet interfaces

Author

Seemann, KM, Gomonay, O, Mokrousov, Y, Hörner, A, Valencia, S, Klamser, P, Kronast, F, Erb, A, Hindmarch, AT, Wixforth, A, Marrows, CH, and Fischer, P

Subjects
Physical Sciences, Classical Physics, Chemical sciences, Engineering, Physical sciences
Abstract

In prototype ferromagnet-antiferromagnet interfaces we demonstrate that surface acoustic waves can be used to identify complex magnetic phases arising upon evolution of exchange springs in an applied field. Applying sub-GHz surface acoustic waves to study the domain structure of the ferromagnetic layer in exchange-biased bilayers of Ir20Mn80-Co60Fe20B20, we are able to associate the magnetoelastic resonance with the presence of the exchange spin-spirals in both the ferromagnetic and antiferromagnetic layer. Our findings offer a complementary, integrative insight into emergent magnetic materials for applications of noncollinear spin textures in view of low-energy-consumption spintronic devices.

Published
2022

14. Antiferromagnetic Hysteresis above the Spin Flop Field

Author

Grzybowski, M. J., Schippers, C. F., Gomonay, O., Rubi, K., Bal, M. E., Zeitler, U., Kozioł-Rachwał, A., Szpytma, M., Janus, W., Kurowska, B., Kret, S., Gryglas-Borysiewicz, M., Koopmans, B., and Swagten, H. J. M.

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

Magnetocrystalline anisotropy is essential in the physics of antiferromagnets and commonly treated as a constant, not depending on an external magnetic field. However, we demonstrate that in CoO the anisotropy should necessarily depend on the magnetic field, which is shown by the spin Hall magnetoresistance of the CoO $|$ Pt device. Below the N\'eel temperature CoO reveals a spin-flop transition at 240 K at 7.0 T, above which a hysteresis in the angular dependence of magnetoresistance unexpectedly persists up to 30 T. This behavior is shown to agree with the presence of the unquenched orbital momentum, which can play an important role in antiferromagnetic spintronics.

Published
2021

15. Magnon Transport in the Presence of Antisymmetric Exchange in a Weak Antiferromagnet

Author

Ross, A., Lebrun, R., Gomonay, O., Sinova, J., Kay, A., Grave, D. A., Rothschild, A., and Kläui, M.

Subjects
Condensed Matter - Materials Science
Abstract

The Dzyaloshinskii-Moriya interaction (DMI) is at the heart of many modern developments in the research field of spintronics. DMI is known to generate noncollinear magnetic textures, and can take two forms in antiferromagnets: homogeneous or inter-sublattice, leading to small, canted moments and inhomogeneous or intra-sublattice, leading to formation of chiral structures. In this work, we first determine the strength of the effective field created by the DMI, using SQUID based magnetometry and transport measurements, in thin films of the antiferromagnetic iron oxide hematite, $\alpha$-Fe$_2$O$_3$. We demonstrate that DMI additionally introduces reconfigurability in the long distance magnon transport in these films under different orientations of a magnetic field. This arises as a hysteresis centred around the easy-axis direction for an external field rotated in opposing directions whose width decreases with increasing magnetic field as the Zeeman energy competes with the effective field created by the DMI.

Published
2021
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16. Readout of a antiferromagnetic spintronics systems by strong exchange coupling of Mn2Au and Permalloy

Author

Bommanaboyena, S. P., Backes, D., Veiga, L. S. I., Dhesi, S. S., Niu, Y. R., Sarpi, B., Denneulin, T., Kovacs, A., Mashoff, T., Gomonay, O., Sinova, J., Everschor-Sitte, K., Schönke, D., Reeve, R. M., Kläui, M., Elmers, H. -J., and Jourdan, M.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter
Abstract

In antiferromagnetic spintronics, the read-out of the staggered magnetization or Neel vector is the key obstacle to harnessing the ultra-fast dynamics and stability of antiferromagnets for novel devices. Here, we demonstrate strong exchange coupling of Mn2Au, a unique metallic antiferromagnet that exhibits Neel spin-orbit torques, with thin ferromagnetic Permalloy layers. This allows us to benefit from the well-estabished read-out methods of ferromagnets, while the essential advantages of antiferromagnetic spintronics are retained. We show one-to-one imprinting of the antiferromagnetic on the ferromagnetic domain pattern. Conversely, alignment of the Permalloy magnetization reorients the Mn2Au Neel vector, an effect, which can be restricted to large magnetic fields by tuning the ferromagnetic layer thickness. To understand the origin of the strong coupling, we carry out high resolution electron microscopy imaging and we find that our growth yields an interface with a well-defined morphology that leads to the strong exchange coupling., Comment: 9 pages, 5 figures

Published
2021
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17. Effective strain manipulation of the antiferromagnetic state of polycrystalline NiO

Author

Barra, A., Ross, A., Gomonay, O., Baldrati, L., Chavez, A., Lebrun, R., Schneider, J. D., Shirazi, P., Wang, Q., Sinova, J., Carman, G. P., and Kläui, M.

Subjects
Condensed Matter - Materials Science
Abstract

As a candidate material for applications such as magnetic memory, polycrystalline antiferromagnets offer the same robustness to external magnetic fields, THz spin dynamics, and lack of stray field as their single crystalline counterparts, but without the limitation of epitaxial growth and lattice matched substrates. Here, we first report the detection of the average Neel vector orientiation in polycrystalline NiO via spin Hall magnetoresistance (SMR). Secondly, by applying strain through a piezo-electric substrate, we reduce the critical magnetic field required to reach a saturation of the SMR signal, indicating a change of the anisotropy. Our results are consistent with polycrystalline NiO exhibiting a positive sign of the in-plane magnetostriction. This method of anisotropy-tuning offers an energy efficient, on-chip alternative to manipulate a polycrystalline antiferromagnets magnetic state.

Published
2021
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18. Ultrafast amplification and non-linear magneto-elastic coupling of coherent magnon modes in an antiferromagnet

Author

Bossini, D., Pancaldi, M., Soumah, L., Basini, M., Mertens, F., Cinchetti, M., Satoh, T., Gomonay, O., and Bonetti, S.

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

We investigate the role of domain walls in the ultrafast magnon dynamics of an antiferromagnetic NiO single crystal in a pump-probe experiment with variable pump photon energy. Analysing the amplitude of the energy-dependent photo-induced ultrafast spin dynamics, we detect a yet unreported coupling between the material's characteristic THz- and a GHz-magnon modes. We explain this unexpected coupling between two orthogonal eigenstates of the corresponding Hamiltonian by modelling the magneto-elastic interaction between spins in different domains. We find that such interaction, in the non-linear regime, couples the two different magnon modes via the domain walls and it can be optically exploited via the exciton-magnon resonance., Comment: 6 pages, 4 figures

Published
2021
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19. Direct imaging of current-induced antiferromagnetic switching revealing a pure thermomagnetoelastic switching mechanism

Author

Meer, H., Schreiber, F., Schmitt, C., Ramos, R., Saitoh, E., Gomonay, O., Sinova, J., Baldrati, L., and Kläui, M.

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

We unravel the origin of current-induced magnetic switching of insulating antiferromagnet/heavy metal systems. We utilize concurrent transport and magneto-optical measurements to image the switching of antiferromagnetic domains in specially engineered devices of NiO/Pt bilayers. Different electrical pulsing and device geometries reveal different final states of the switching with respect to the current direction. We can explain these through simulations of the temperature induced strain and we identify the thermomagnetoelastic switching mechanism combined with thermal excitations as the origin, in which the final state is defined by the strain distributions and heat is required to switch the antiferromagnetic domains. We show that such a potentially very versatile non-contact mechanism can explain the previously reported contradicting observations of the switching final state, which were attributed to spin-orbit torque mechanisms.

Published
2020
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20. Magnetoresistance effects in the metallic antiferromagnet Mn$_2$Au

Author

Bodnar, S. Yu., Skourski, Y., Gomonay, O., Sinova, J., Kläui, M., and Jourdan, M.

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

In antiferromagnetic spintronics, it is essential to separate the resistance modifications of purely magnetic origin from other effects generated by current pulses intended to switch the N\'eel vector. We investigate the magnetoresistance effects resulting from magnetic field induced reorientations of the staggered magnetization of epitaxial antiferromagnetic Mn2Au(001) thin films. The samples were exposed to 60 T magnetic field pulses along different crystallographic in-plane directions of Mn2Au(001), while their resistance was measured. For the staggered magnetization aligned via a spin-flop transition parallel to the easy [110]-direction, an ansiotropic magnetoresistance of -0.15 % was measured. In the case of a forced alignment of the staggered magnetization parallel to the hard [100]-direction, evidence for a larger anisotropic magnetoresistance effect was found. Furthermore, transient resistance reductions of about 1 % were observed, which we associate with the annihilation of antiferromagnetic domain walls by the magnetic field pulses., Comment: 6 pages, 4 figures

Published
2019
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21. N\'{e}el Spin Orbit Torque driven antiferromagnetic resonance in Mn$_{2}$Au probed by time-domain THz spectroscopy

Author

Bhattacharjee, N., Sapozhnik, A. A., Bodnar, S. Yu., Grigorev, V. Yu., Agustsson, S. Y., Cao, J., Dominko, D., Obergfell, M., Gomonay, O., Sinova, J., Kläui, M., Elmers, H. -J., Jourdan, M., and Demsar, J.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

We observe the excitation of collective modes in the THz range driven by the recently discovered N\'{e}el spin-orbit torques (NSOT) in the metallic antiferromagnet Mn$_{2}$Au. Temperature dependent THz spectroscopy reveals a strong absorption mode centered near 1 THz, which upon heating from 4 K to 450 K softens and looses intensity. Comparison with the estimated eigenmode frequencies implies that the observed mode is an in-plane antiferromagnetic resonance (AFMR) mode. The AFMR absorption strength exceeds those found in antiferromagnetic insulators, driven by the magnetic field of the THz radiation, by three orders of magnitude. Based on this and the agreement with our theory modelling, we infer that the driving mechanism for the observed mode is the current induced NSOT. This electric manipulation of the Ne\'{e}l order parameter at high frequencies makes Mn$_{2}$Au a prime candidate for AFM ultrafast memory applications., Comment: 5 pages, 4 figures

Published
2018
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22. Narrow-band tunable THz detector in antiferromagnets via N\'eel spin-orbit torque and spin-transfer torque

Author

Gomonay, O., Jungwirth, T., and Sinova, J.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study dynamics of antiferromagnets induced by simultaneous application of dc spin current and ac charge current, motivated by the requirement of all-electrically controlled devices in THz gap (0.1-30 THz). We show that ac electric current, via N\'eel spin orbit torques, can lock the phase of a steady rotating N\'eel vector whose precession is controlled by a dc spin current. In the phase-locking regime the frequency of the incoming ac signal coincides with the frequency of autooscillations which for typical antiferromagnets fall into the THz range. The frequency of autooscillations is proportional to the precession-induced tilting of the magnetic sublattices related to the so-called dynamical magnetization. We show how the incoming ac signal can be detected from the measurement of the dc-current dependencies of the constant dynamical magnetization. We formulate the conditions of phase-locking based on relations between parameters of an antiferromagnet and the characteristics of the incoming signal (frequency, amplitude, bandwidth, duration). We also show that the rotating N\'eel vector can generate ac electrical current via inverse N\'eel spin-orbit torque. Hence, antiferromagnets driven by dc spin current can be used as tunable detectors and emitters of narrow-band signals operating in the THz range., Comment: 5 pages, 5 figures

Published
2017
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24. Laser-driven quantum magnonics and THz dynamics of the order parameter in antiferromagnets

Author

Bossini, D., Conte, S. Dal, Gomonay, O., Pisarev, R. V., Borovsak, M., Mihailovic, D., Sinova, J., Cerullo, G., Mentink, J. H., Rasing, Th., and Kimel, A. V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons
Abstract

The impulsive generation of two-magnon modes in antiferromagnets by femtosecond optical pulses, so-called femto-nanomagnons, leads to coherent longitudinal oscillations of the antiferromagnetic order parameter that cannot be described by a thermodynamic Landau-Lifshitz approach. We argue that this dynamics is triggered as a result of a laser-induced modification of the exchange interaction. In order to describe the oscillations we have formulated a quantum mechanical description in terms of magnon pair operators and coherent states. Such an approach allowed us to} derive an effective macroscopic equation of motion for the temporal evolution of the antiferromagnetic order parameter. An implication of the latter is that the photo-induced spin dynamics represents a macroscopic entanglement of pairs of magnons with femtosecond period and nanometer wavelength. By performing magneto-optical pump-probe experiments with 10 femtosecond resolution in the cubic KNiF$_3$ and the uniaxial K$_2$NiF$_4$ collinear Heisenberg antiferromagnets, we observed coherent oscillations at the frequency of 22 THz and 16 THz, respectively. The detected frequencies as a function of the temperature ideally fit the two-magnon excitation up to the N\'eel point. The experimental signals are described as dynamics of magnetic linear dichroism due to longitudinal oscillations of the antiferromagnetic vector., Comment: 25 pages, 10 figures

Published
2017
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25. Writing and Reading antiferromagnetic Mn$_2$Au: N\'eel spin-orbit torques and large anisotropic magnetoresistance

Author

Bodnar, S. Yu., Šmejkal, L., Turek, I., Jungwirth, T., Gomonay, O., Sinova, J., Sapozhnik, A. A., Elmers, H. -J., Kläui, M., and Jourdan, M.

Subjects
Condensed Matter - Materials Science
Abstract

Antiferromagnets are magnetically ordered materials which exhibit no net moment and thus are insensitive to magnetic fields. Antiferromagnetic spintronics aims to take advantage of this insensitivity for enhanced stability, while at the same time active manipulation up to the natural THz dynamic speeds of antiferromagnets is possible, thus combining exceptional storage density and ultra-fast switching. However, the active manipulation and read-out of the N\'eel vector (staggered moment) orientation is challenging. Recent predictions have opened up a path based on a new spin-orbit torque, which couples directly to the N\'eel order parameter. This N\'eel spin-orbit torque was first experimentally demonstrated in a pioneering work using semimetallic CuMnAs. Here we demonstrate for Mn$_2$Au, a good conductor with a high ordering temperature suitable for applications, reliable and reproducible switching using current pulses and readout by magnetoresistance measurements. The symmetry of the torques agrees with theoretical predictions and a large read-out magnetoresistance effect of more than $\simeq 6$~$\%$ is reproduced by ab initio transport calculations., Comment: 5 pages, 4 figures

Published
2017
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26. Concepts of antiferromagnetic spintronics

Author

Gomonay, O., Jungwirth, T., and Sinova, J.

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

Antiferromagnetic spintronics is an emerging research field whose focus is on the electrical and optical control of the antiferromagnetic order parameter and its utility in information technology devices. An example of recently discovered new concepts is the N\'{e}el spin-orbit torque which allows for the antiferromagnetic order parameter to be controlled by an electrical current in common microelectronic circuits. In this review we discuss the utility of antiferromagnets as active and supporting materials for spintronics, the interplay of antiferromagnetic spintronics with other modern research fields in condensed matter physics, and its utility in future "More than Moore" information technologies., Comment: Overview of the topics presented at the Workshop of Antiferromagnetic Spintronics, 2016, Mainz, Germany

Published
2017
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28. Skyrmions and multi-sublattice helical states in a frustrated chiral magnet

Author

Yuan, H. Y., Gomonay, O., and Kläui, Mathias

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

We investigate the existence and stability of skyrmions in a frustrated chiral ferromagnet by considering the competition between ferromagnetic (FM) nearest-neighbour (NN) interaction ($J_1$) and antiferromagnetic (AFM) next-nearest-neighbour (NNN) interaction ($J_2$). Contrary to the general wisdom that long-range ferromagnetic order is not energy preferable under frustration, the skyrmion lattice not only exists but is even stable for a large field range when $J_2 \leq J_1$ compared with frustration-free systems. We defend that the enlargement of stability window of skyrmions is a consequence of the reduced effective exchange interaction caused by the frustration. A multi-sublattice helical state is found below the skyrmion phase, which results from the competition between AFM coupling that favors a two-sublattice N\'{e}el state and the chiral interaction that prefers a helix. As a byproduct, the hysteresis loop of the frustrated chiral system shrinks as the magnetization goes to zero and then opens up again, known as wasp-waist hysteresis loop. The critical field that separates the narrow and wide part of the wasp-waist loop depends exponentially on the strength of NNN coupling. By measuring the critical field, it is possible to determine the strength of NNN coupling., Comment: 7 pages, 5 figures; references added

Published
2016
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29. Staggering antiferromagnetic domain wall velocity in a staggered spin-orbit field

Author

Gomonay, O., Jungwirth, T., and Sinova, J.

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

We demonstrate the possibility to drive an antiferromagnet domain-wall at high velocities by field-like N\'{e}el spin-orbit torques. Such torques arise from current-induced local fields that alternate their orientation on each sub-lattice of the antiferromagnet and whose orientation depend primarily on the current direction, giving them their field-like character. The domain-wall velocities that can be achieved by this mechanism are two orders of magnitude greater than the ones in ferromagnets. This arises from the efficiency of the staggered spin-orbit fields to couple to the order parameter and from the exchange-enhanced phenomena in antiferromagnetic texture dynamics, which leads to a low domain-wall effective mass and the absence of a Walker break-down limit. In addition, because of its nature, the staggered spin-orbit field can lift the degeneracy between two 180$^\circ$ rotated states in a collinear antiferromagnet and provides a force that can move such walls and control the switching of the states., Comment: 9 pages, Supplementary materials included

Published
2016
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34. Antiferromagnetic hysteresis above the spin-flop field

Author

Grzybowski, M.J., Schippers, C.F., Gomonay, O., Rubi, K., Bal, M.E., Zeitler, U., Kozioł-Rachwał, A., Szpytma, M., Janus, W., Kurowska, B., Kret, S., Gryglas-Borysiewicz, M., Koopmans, B., Swagten, H.J.M., Grzybowski, M.J., Schippers, C.F., Gomonay, O., Rubi, K., Bal, M.E., Zeitler, U., Kozioł-Rachwał, A., Szpytma, M., Janus, W., Kurowska, B., Kret, S., Gryglas-Borysiewicz, M., Koopmans, B., and Swagten, H.J.M.

Abstract

Contains fulltext : 292809.pdf (Publisher’s version ) (Open Access)

Published
2023

35. Antiferromagnet-mediated interlayer exchange : Hybridization versus proximity effect

Author

Polishchuk, Dmytr, Tykhonenko Polishchuk, Yuliya, Lytvynenko, Ya M., Rostas, A. M., Kuncser, V., Kravets, Anatolii, Tovstolytkin, A. I., Gomonay, O. V., Korenivski, Vladislav, Polishchuk, Dmytr, Tykhonenko Polishchuk, Yuliya, Lytvynenko, Ya M., Rostas, A. M., Kuncser, V., Kravets, Anatolii, Tovstolytkin, A. I., Gomonay, O. V., and Korenivski, Vladislav

Abstract

We investigate the interlayer coupling between two thin ferromagnetic (F) films mediated by an antiferromagnetic (AF) spacer in F∗/AF/F trilayers and show how it transitions between different regimes on changing the AF thickness. Employing layer-selective Kerr magnetometry and ferromagnetic-resonance techniques in a complementary manner enables us to distinguish between three functionally distinct regimes of such ferromagnetic interlayer coupling. The F layers are found to be individually and independently exchange-biased for thick FeMn spacers - the first regime of no interlayer F-F∗ coupling. F-F∗ coupling appears on decreasing the FeMn thickness below 9 nm. In this second regime found in structures with 6.0-9.0-nm-thick FeMn spacers, the interlayer coupling exists only in a finite temperature interval just below the effective Néel temperature of the spacer, which is due to magnon-mediated exchange through the thermally softened antiferromagnetic spacer, vanishing at lower temperatures. The third regime, with FeMn thinner than 4 nm, is characterized by a much stronger interlayer coupling in the entire temperature interval, which is attributed to a magnetic-proximity induced ferromagnetic exchange. These experimental results, spanning the key geometrical parameters and thermal regimes of the F∗/AF/F nanostructure, complemented by a comprehensive theoretical analysis, should broaden the understanding of the interlayer exchange in magnetic multilayers and potentially be useful for applications in spin thermionics., QC 20230823

Published
2023
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37. Terahertz Néel spin-orbit torques drive nonlinear magnon dynamics in antiferromagnetic Mn2Au.

Author

Behovits, Y., Chekhov, A. L., Bodnar, S. Yu., Gueckstock, O., Reimers, S., Lytvynenko, Y., Skourski, Y., Wolf, M., Seifert, T. S., Gomonay, O., Kläui, M., Jourdan, M., and Kampfrath, T.

Subjects
MAGNONS, SPIN-orbit interactions, ELECTROMAGNETIC pulses, TORQUE, MAGNETIC control, SYMMETRY breaking, ELECTRIC fields
Abstract

Antiferromagnets have large potential for ultrafast coherent switching of magnetic order with minimum heat dissipation. In materials such as Mn2Au and CuMnAs, electric rather than magnetic fields may control antiferromagnetic order by Néel spin-orbit torques (NSOTs). However, these torques have not yet been observed on ultrafast time scales. Here, we excite Mn2Au thin films with phase-locked single-cycle terahertz electromagnetic pulses and monitor the spin response with femtosecond magneto-optic probes. We observe signals whose symmetry, dynamics, terahertz-field scaling and dependence on sample structure are fully consistent with a uniform in-plane antiferromagnetic magnon driven by field-like terahertz NSOTs with a torkance of (150 ± 50) cm2 A−1 s−1. At incident terahertz electric fields above 500 kV cm−1, we find pronounced nonlinear dynamics with massive Néel-vector deflections by as much as 30°. Our data are in excellent agreement with a micromagnetic model. It indicates that fully coherent Néel-vector switching by 90° within 1 ps is within close reach. Néel spin-orbit torques can occur in antiferromagnets with broken inversion symmetry, such as Mn2Au, and have garnered significant interest recently, as they allow for the electrical control of the antiferromagnetic ordering. Here, Behovits et al. apply intense terahertz electric fields to Mn2Au and observe the deflection of the Néel vector on ultrafast time scales due to Néel spin-orbit torques. [ABSTRACT FROM AUTHOR]

Published
2023
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39. Antiferromagnetic hysteresis above the spin-flop field

Author

Grzybowski, M. J., primary, Schippers, C. F., additional, Gomonay, O., additional, Rubi, K., additional, Bal, M. E., additional, Zeitler, U., additional, Kozioł-Rachwał, A., additional, Szpytma, M., additional, Janus, W., additional, Kurowska, B., additional, Kret, S., additional, Gryglas-Borysiewicz, M., additional, Koopmans, B., additional, and Swagten, H. J. M., additional

Published
2023
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40. Evidence of non-degenerated, non-reciprocal and ultra-fast spin-waves in the canted antiferromagnet {\alpha}-Fe2O3

Author

Kanj, A. El, Gomonay, O., Boventer, I., Bortolotti, P., Cros, V., Anane, A., and Lebrun, R.

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

Spin-waves in antiferromagnets hold the prospects for the development of faster, less power-hungry electronics, as well as new physics based on spin-superfluids and coherent magnon-condensates. For both these perspectives, addressing electrically coherent antiferromagnetic spin-waves is of importance, a prerequisite that has so far been elusive, because unlike ferromagnets, antiferromagnets couple weakly to radiofrequency fields. Here, we demonstrate the electrical detection of ultra-fast non-reciprocal spin-waves in the dipolar-exchange regime of a canted antiferromagnet. Using time-of-flight spin-wave spectroscopy on hematite (alpha-Fe2O3), we find that the magnon wave packets can propagate as fast as 30 km/s for reciprocal bulk spin-wave modes and up to 10 km/s for surface-spin waves propagating parallel to the antiferromagnetic N\'eel vector. The electrical detection of coherent non-reciprocal antiferromagnetic spin waves holds makes hematite a versatile platform where most of the magnonic concepts developed for ferromagnet can be adapted paving the way for the development antiferromagnetic and altermagnet-based magnonic devices.

Published
2023

41. Evidence of non-degenerated, non-reciprocal and ultra-fast spin-waves in the canted antiferromagnet α-Fe2O3

Author

Kanj, A. El, Gomonay, O., Boventer, I., Bortolotti, P., Cros, V., Anane, A., and Lebrun, R.

Subjects
Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Applied Physics (physics.app-ph), Other Condensed Matter (cond-mat.other)
Abstract

Spin-waves in antiferromagnets hold the prospects for the development of faster, less power-hungry electronics, as well as new physics based on spin-superfluids and coherent magnon-condensates. For both these perspectives, addressing electrically coherent antiferromagnetic spin-waves is of importance, a prerequisite that has so far been elusive, because unlike ferromagnets, antiferromagnets couple weakly to radiofrequency fields. Here, we demonstrate the electrical detection of ultra-fast non-reciprocal spin-waves in the dipolar-exchange regime of a canted antiferromagnet. Using time-of-flight spin-wave spectroscopy on hematite (alpha-Fe2O3), we find that the magnon wave packets can propagate as fast as 30 km/s for reciprocal bulk spin-wave modes and up to 10 km/s for surface-spin waves propagating parallel to the antiferromagnetic Néel vector. The electrical detection of coherent non-reciprocal antiferromagnetic spin waves holds makes hematite a versatile platform where most of the magnonic concepts developed for ferromagnet can be adapted paving the way for the development antiferromagnetic and altermagnet-based magnonic devices.

Published
2023
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44. Photocurrents, inverse Faraday effect, and photospin Hall effect in Mn2Au.

Author

Merte, M., Freimuth, F., Go, D., Adamantopoulos, T., Lux, F. R., Plucinski, L., Gomonay, O., Blügel, S., and Mokrousov, Y.

Subjects
HALL effect, FARADAY effect, PHOTOCURRENTS, SPIN Hall effect, ANTIFERROMAGNETIC materials
Abstract

Among antiferromagnetic materials, Mn2Au is one of the most intensively studied, and it serves as a very popular platform for testing various ideas related to antiferromagnetic magnetotransport and dynamics. Since recently, this material has also attracted considerable interest in the context of optical properties and optically-driven antiferromagnetic switching. In this work, we use first principles methods to explore the physics of charge photocurrents, spin photocurrents, and the inverse Faraday effect in antiferromagnetic Mn2Au. We predict the symmetry and magnitude of these effects and speculate that they can be used for tracking the dynamics of staggered moments during switching. Our calculations reveal the emergence of large photocurrents of spin in collinear Mn2Au, whose properties can be understood as a result of a non-linear optical version of the spin Hall effect, which we refer to as the photospin Hall effect, encoded into the relation between the driving charge and resulting spin photocurrents. Moreover, we suggest that even a very small canting in Mn2Au can give rise to colossal spin photocurrents that are chiral in flavor. We conclude that the combination of staggered magnetization with the structural and electronic properties of this material results in a unique blend of prominent photocurrents, which makes Mn2Au a unique platform for advanced optospintronics applications. [ABSTRACT FROM AUTHOR]

Published
2023
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45. Photocurrents of charge and spin in monolayer Fe3GeTe2

Author

Merte, M., primary, Freimuth, F., additional, Adamantopoulos, T., additional, Go, D., additional, Saunderson, T. G., additional, Kläui, M., additional, Plucinski, L., additional, Gomonay, O., additional, Blügel, S., additional, and Mokrousov, Y., additional

Published
2021
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46. Readout of an antiferromagnetic spintronics system by strong exchange coupling of Mn2Au and Permalloy

Author

Bommanaboyena, S. P., primary, Backes, D., additional, Veiga, L. S. I., additional, Dhesi, S. S., additional, Niu, Y. R., additional, Sarpi, B., additional, Denneulin, T., additional, Kovács, A., additional, Mashoff, T., additional, Gomonay, O., additional, Sinova, J., additional, Everschor-Sitte, K., additional, Schönke, D., additional, Reeve, R. M., additional, Kläui, M., additional, Elmers, H.-J., additional, and Jourdan, M., additional

Published
2021
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47. Anisotropic long-range spin transport in canted antiferromagnetic orthoferrite YFeO3.

Author

Das, Shubhankar, Ross, A., Ma, X. X., Becker, S., Schmitt, C., van Duijn, F., Galindez-Ruales, E. F., Fuhrmann, F., Syskaki, M.-A., Ebels, U., Baltz, V., Barra, A.-L., Chen, H. Y., Jakob, G., Cao, S. X., Sinova, J., Gomonay, O., Lebrun, R., and Kläui, M.

Subjects
ANTIFERROMAGNETIC materials, SPIN waves, GROUP velocity, MAGNETIC fields, INFORMATION processing, CHOICE of transportation, HEMATITE
Abstract

In antiferromagnets, the efficient transport of spin-waves has until now only been observed in the insulating antiferromagnet hematite, where circularly (or a superposition of pairs of linearly) polarized spin-waves diffuse over long distances. Here, we report long-distance spin-transport in the antiferromagnetic orthoferrite YFeO3, where a different transport mechanism is enabled by the combined presence of the Dzyaloshinskii-Moriya interaction and externally applied fields. The magnon decay length is shown to exceed hundreds of nanometers, in line with resonance measurements that highlight the low magnetic damping. We observe a strong anisotropy in the magnon decay lengths that we can attribute to the role of the magnon group velocity in the transport of spin-waves in antiferromagnets. This unique mode of transport identified in YFeO3 opens up the possibility of a large and technologically relevant class of materials, i.e., canted antiferromagnets, for long-distance spin transport. Antiferromagnets have attracted interest for spin-based information processing due to their resilience to stray magnetic fields and extremely rapid spin dynamics, however, long range spin wave transport has only been shown in one type of antiferromagnet thus far. Here, Das et al demonstrate long range spin wave transport in antiferromagnetic YFeO3. [ABSTRACT FROM AUTHOR]

Published
2022
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