Your search keyword '"Lindner J"' showing total 2,935 results

1. Reconstruction of Angstrom resolution exit-waves by the application of drift-corrected phase-shifting off-axis electron holography

Author

Lindner, J., Ross, U., Meyer, T., Boureau, V., Seibt, M., and Jooss, Ch.

Subjects

Condensed Matter - Materials Science

Abstract

Phase-shifting electron holography is an excellent method to reveal electron wave phase information with very high phase sensitivity over a large range of spatial frequencies. It circumvents the limiting trade-off between fringe spacing and visibility of standard off-axis holography. Previous implementations have been limited by the independent drift of biprism and sample. We demonstrate here an advanced drift correction scheme for the hologram series that exploits the presence of an interface of the TEM specimen to the vacuum area in the hologram. It allows to obtain reliable phase information up to 2{\pi}/452 at the 1 {\AA} information limit of the Titan 80-300 kV environmental transmission electron microscope used, by applying a moderate voltage of 250 V to a single biprism for a fringe spacing of 1 {\AA}. The obtained phase and amplitude information is validated at a thin Pt sample by use of multislice image simulation with the frozen lattice approximation and shows excellent agreement. The presented method is applicable in any TEM equipped with at least one electron biprism and thus enables achieving high resolution off-axis holography in various instruments including those for in-situ applications. A software implementation for the acquisition, calibration and reconstruction is provided., Comment: Text changes and clarifications from the revision process. Added SI to the PDF

Published

2023

2. Reconstruction of Angstrom resolution exit-waves by the application of drift-corrected phase-shifting off-axis electron holography

Author

Lindner, J., Ross, U., Meyer, T., Boureau, V., Seibt, M., and Jooss, Ch.

Published

2024

3. The HEV Ventilator

Author

Buytaert, J., Abud, A. Abed, Allport, P., Álvarez, A. Pazos, Akiba, K., Francisco, O. Augusto de Aguiar, Bay, A., Bernard, F., Baron, S., Bertella, C., Brunner, J., Bowcock, T., Jode, M. Buytaert-De, Byczynski, W., De Carvalho, R., Coco, V., Collins, P., Collins, R., Dikic, N., Dousse, N., Dowd, B., Dumps, R., Durante, P., Fadel, W., Farry, S., Prieto, A. Fernández, Flynn, G., Lima, V. Franco, Frei, R., Torreira, A. Gallas, Guida, R., Hennessy, K., Henriques, A., Hutchcroft, D., Ilic, S., Jevtic, A., Joram, C., Kapusniak, K., Cid, E. Lemos, Lindner, J., Lindner, R., Milovanovic, M., Mico, S., Morant, J., Morel, M., Männe, G., Murray, D., Nasteva, I., Neufeld, N., Neuhold, I., López, F. Pardo-Sobrino, Trigo, E. Pérez, Jallas, G. Pichel, Pilorz, E., Piquilloud, L., Pons, X., Reiner, D., Roosens, C., Rostalski, P., Schmidt, B., Saucet, E., Sanders, F., Sigaud, C., Schoettker, P., Schwemmer, R., Schindler, H., Sharma, A., Svihra, P., van Leemput, J., Vignaux, L., Vasey, F., Woonton, H., and Wyllie, K.

Subjects

Physics - Medical Physics

Abstract

HEV is a low-cost, versatile, high-quality ventilator, which has been designed in response to the COVID-19 pandemic. The ventilator is intended to be used both in and out of hospital intensive care units, and for both invasive and non-invasive ventilation. The hardware can be complemented with an external turbine for use in regions where compressed air supplies are not reliably available. The standard modes provided include PC-A/C(Pressure Assist Control),PC-A/C-PRVC(Pressure Regulated Volume Control), PC-PSV (Pressure Support Ventilation) and CPAP (Continuous Positive airway pressure). HEV is designed to support remote training and post market surveillance via a web interface and data logging to complement the standard touch screen operation, making it suitable for a wide range of geographical deployment. The HEV design places emphasis on the quality of the pressure curves and the reactivity of the trigger, delivering a global performance which will be applicable to ventilator needs beyond theCOVID-19 pandemic. This article describes the conceptual design and presents the prototype units together with their performance evaluation., Comment: 34 pages, 18 figures, Extended version of the article submitted to PNAS

Published

2020

4. Magnetization dynamics in synthetic antiferromagnets: Role of dynamical energy and mutual spin pumping

Author

Sorokin, S., Gallardo, R. A., Fowley, C., Lenz, K., Titova, A., Atcheson, G. Y. P, Dennehy, G., Rode, K., Fassbender, J., Lindner, J., and Deac, A. M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate magnetization dynamics in asymmetric interlayer exchange coupled Py/Ru/Py trilayers using both vector network analyzer-based and electrically detected ferromagnetic resonance techniques. Two different ferromagnetic resonance modes, in-phase and out-of-phase, are observed across all three regimes of the static magnetization configurations, through antiparallel alignment at low fields, the spin-flop transition at intermediate fields, and parallel alignment at high fields. The nonmonotonic behavior of the modes as a function of the external field is explained in detail by analyzing the interlayer exchange and Zeeman energies and is found to be solely governed by the interplay of their dynamical components. In addition, the linewidths of both modes were determined across the three regimes and the different behaviors of the linewidths versus external magnetic field are attributed to mutual spin pumping induced in the samples. Interestingly, the difference between the linewidths of the out-of-phase and in-phase modes decreases at the spin-flop transition and is reversed between the antiparallel and parallel aligned magnetization states.

Published

2020

5. Direct imaging of the ac component of the pumped spin polarization with element specificity

Author

Pile, S., Buchner, M., Ney, V., Schaffers, T., Lenz, K., Narkowicz, R., Lindner, J., Ohldag, H., and Ney, A.

Subjects

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

Abstract

Spin pumping in a ferromagnet/nonferromagnet heterostructure is directly imaged with spatial resolution as well as element selectivity. The time-resolved detection in scanning transmission x-ray microscopy allows to directly probe the spatial extent of the ac spin polarization in Co-doped ZnO which is generated by spin pumping from an adjacent permalloy microstrip. Comparing the relative phases of the dynamic magnetization component of the two constituents is possible and found to be antiphase. The correlation between the distribution of the magnetic excitation in the permalloy and the Co-doped ZnO reveals that laterally there is no one-to-one correlation. The observed distribution is rather complex, but integrating over larger areas clearly demonstrates that the spin polarization in the nonferromagnet extends laterally beyond the region of the ferromagnetic microstrip. Therefore the observations are better explained by a local spin pumping efficieny and a lateral propagation of the ac spin polarization in the nonferromagnet over the range of a few micrometers., Comment: 7 pages, 5 figures

Published

2020

6. The HEV Ventilator Proposal

Author

Buytaert, J., Abud, A. Abed, Akiba, K., Bay, A., Bertella, C., Bowcock, T., Byczynski, W., Coco, V., Collins, P., Francisco, O. Augusto De Aguiar, Dikic, N., Dumps, R., Durante, P., Prieto, A. Fernández, Lima, V. Franco, Guida, R., Hennessy, K., Hutchcroft, D., Ilic, S., Jevtic, A., Kapusniak, K., Cid, E. Lemos, Lindner, J., Milovanovic, M., Murray, D., Nasteva, I., Neufeld, N., Pons, X., Sanders, F., Schwemmer, R., and Svihra, P.

Subjects

Physics - Medical Physics

Abstract

We propose the design of a ventilator which can be easily manufactured and integrated into the hospital environment to support COVID-19 patients. The unit is designed to support standard ventilator modes of operation, most importantly PRVC (Pressure Regulated Volume Control) and SIMV-PC (Synchronised Intermittent Mandatory Ventilation) modes. The unit is not yet an approved medical device and is in the concept and prototyping stage. It is presented here to invite fast feedback for development and deployment in the face of the COVID-19 pandemic., Comment: 14 pages, 5 figures

Published

2020

7. InAs Heteroepitaxy on Nanopillar-Patterned GaAs (111)A

Author

Kunnathully, V. S., Riedl, T., Trapp, A., Langer, T., Reuter, D., and Lindner, J. K. N.

Subjects

Condensed Matter - Materials Science

Abstract

Heteroepitaxy on nanopatterned substrates is a means of defect reduction at semiconductor heterointerfaces by exploiting substrate compliance and enhanced elastic lattice relaxation resulting from reduced dimensions. We explore this possibility in the InAs/GaAs(111)A system using a combination of nanosphere lithography and reactive ion etching of the GaAs(111)A substrate for nano-patterning of the substrate, yielding pillars with honeycomb and hexagonal arrangements and varied nearest neighbor distances. Substrate patterning is followed by MBE growth of InAs at temperatures of 150 - 350 C and growth rates of 0.011 nm/s and 0.11 nm/s. InAs growth in the form of nano-islands on the pillar tops is achieved by lowering the adatom migration length by choosing a low growth temperature of 150 C at the growth rate 0.011 nm/s. The choice of a higher growth rate of 0.11 nm/s results in higher InAs island nucleation and the formation of hillocks concentrated at the pillar bases due to a further reduction of adatom migration length. A common feature of the growth morphology for all other explored conditions is the formation of merged hillocks or pyramids with well-defined facets due to the presence of a concave surface curvature at the pillar bases acting as adatom sinks.

Published

2019

8. Strain-driven InAs island growth on top of GaAs(111) nanopillars

Author

Riedl, T., Kunnathully, V. S., Trapp, A., Langer, T., Reuter, D., and Lindner, J. K. N.

Subjects

Condensed Matter - Materials Science

Abstract

We analyze the shape and position of heteroepitaxial InAs islands on the top face of cylindrical GaAs(111)A nanopillars experimentally and theoretically. Catalyst-free molecular beam epitaxial growth of InAs at low temperatures on GaAs nanopillars results in InAs islands with diameters < 30 nm exhibiting predominantly rounded triangular in-plane shapes. The islands show a tendency to grow at positions displaced from the center towards the pillar edge. Atomistic molecular statics simulations evidence that triangular-prismatic islands centered to the pillar axis with diameters smaller than that of the nanopillars are energetically favored. Moreover, we reveal the existence of minimum-energy states for off-axis island positions, in agreement with the experiment. These findings are interpreted by evaluating the spatial strain distributions and the number of broken bonds of surface atoms as a measure for the surface energy. The preferred off-axis island positions can be understood in terms of an increased compliancy of the GaAs nanopillar beneath the island because of the vicinity of free surfaces, leading to a reduction of strain energy. The influence of surface steps on the energy of the system is addressed as well., Comment: 18 pages, 4 figures. Paper updated to match published version

Published

2019

9. Langmuir analysis of electron beam induced plasma in environmental TEM

Author

Lindner, J., Ross, U., Roddatis, V., and Jooss, Ch.

Published

2023

10. Self-stabilizing exchange-mediated spin transport

Author

Schneider, T., Hill, D., Kákay, A., Lenz, K., Lindner, J., Fassbender, J., Upadhyaya, P., Liu, Yuxiang, Wang, Kang, Tserkovnyak, Y., Krivorotov, I. N., and Barsukov, I.

Subjects

Condensed Matter - Other Condensed Matter

Abstract

Long-range spin transport in magnetic systems can be achieved by means of exchange-mediated spin textures with robust topological winding -- a phenomenon referred to as spin superfluidity. Its experimental signatures have been discussed in antiferromagnets which are nearly free of dipolar interaction. However, in ferromagnets, which possess non-negligible dipole fields, realization of such spin transport has remained a challenge. Using micromagnetic simulations, we investigate coherent exchange-mediated spin transport in extended thin ferromagnetic films. We uncover a two-fluid state, in which the long-range spin transport by spin textures co-exists with spin waves, as well as a soliton-screened spin transport regime at high spin injection biases. Both states are associated with distinct spin texture reconstructions near the spin injection region and sustain spin transport over large distances.

Published

2018

11. Emission and Propagation of Multi-Dimensional Spin Waves with nanoscale wavelengths in Anisotropic Spin Textures

Author

Sluka, V., Schneider, T., Gallardo, R. A., Kakay, A., Weigand, M., Warnatz, T., Mattheis, R., Roldan-Molina, A., Landeros, P., Tiberkevich, V., Slavin, A., Schütz, G., Erbe, A., Deac, A., Lindner, J., Raabe, J., Fassbender, J., and Wintz, S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Spin waves offer intriguing novel perspectives for computing and signal processing, since their damping can be lower than the Ohmic losses in conventional CMOS circuits. For controlling the spatial extent and propagation of spin waves on the actual chip, magnetic domain walls show considerable potential as magnonic waveguides. However, low-loss guidance of spin waves with nanoscale wavelengths, in particular around angled tracks, remains to be shown. Here we experimentally demonstrate that such advanced control of propagating spin waves can be obtained using natural features of magnetic order in an interlayer exchange-coupled, anisotropic ferromagnetic bilayer. Using Scanning Transmission X-Ray Microscopy, we image generation of spin waves and their propagation across distances exceeding multiple times the wavelength, in extended planar geometries as well as along one-dimensional domain walls, which can be straight and curved. The observed range of wavelengths is between 1 {\mu}m and 150 nm, at corresponding excitation frequencies from 250 MHz to 3 GHz. Our results show routes towards practical implementation of magnonic waveguides employing domain walls in future spin wave logic and computational circuits.

Published

2018

12. Flat Bands, Indirect Gaps, and Unconventional Spin-Wave Behavior Induced by a Periodic Dzyaloshinskii-Moriya Interaction

Author

Gallardo, R. A., Cortés-Ortuño, D., Schneider, T., Roldán-Molina, A., Ma, Fusheng, Troncoso, R. E., Lenz, K., Fangohr, H., Lindner, J., and Landeros, P.

Subjects

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

Abstract

Periodically patterned metamaterials are known for exhibiting wave properties similar to the ones observed in electronic band structures in crystal lattices. In particular, periodic ferromagnetic materials are characterized by the presence of bands and bandgaps in their spin-wave spectrum at tunable GHz frequencies. Recently, the fabrication of magnets hosting Dzyaloshinskii-Moriya interactions has been pursued with high interest since properties such as the stabilization of chiral spin textures and nonreciprocal spin-wave propagation emerge from this antisymmetric exchange coupling. In this context, to further engineer the magnon band structure, we propose the implementation of magnonic crystals with periodic Dzyaloshinskii-Moriya interactions, which can be obtained, for instance, via patterning of periodic arrays of heavy-metals wires on top of an ultrathin magnetic film. We demonstrate through theoretical calculations and micromagnetic simulations that such systems show an unusual evolution of the standing spin waves around the gaps in areas of the film that are in contact with the heavy-metal wires. We also predict the emergence of indirect gaps and flat bands and, effects that depend on the strength of the Dzyaloshinskii-Moriya interaction. This study opens new routes towards engineered metamaterials for spin-wave-based devices., Comment: 6 pages, 3 figures

Published

2018

13. The complete micromagnetic characterization of asymmetrically sandwiched ferromagnetic films

Author

Kopte, M., Rößler, U. K., Schäfer, R., Kosub, T., Kákay, A., Volkov, O., Fuchs, H., Vedmedenko, E. Y., Radu, F., Schmidt, O. G., Lindner, J., Faßbender, J., and Makarov, D.

Subjects

Condensed Matter - Materials Science

Abstract

The magnetic properties of ferromagnetic thin films down to the nanoscale are ruled by the exchange stiffness, anisotropies and the effects of magnetic fields. As surfaces break inversion symmetry, an additional effective chiral exchange is omnipresent in any magnetic nanostructure. These so-called Dzyaloshinskii-Moriya interactions (DMI) affect all inhomogeneous magnetic states either subtly or spectacularly. E.g., DMIs cause a chirality selection of the rotation sense and can fix the local rotation axis for the magnetization in domain walls (DW). But, they can stabilize also entirely different twisted magnetic structures. The chiral skyrmions a two-dimensional particle-like topological soliton is the ultimately smallest of these objects, which currently is targetted as a possible information carrier in novel spintronic devices. Observation and quantification of the chiral exchange effects provide for the salient point in understanding magnetic properties in ultrathin films and other nanostructures. An easy and reliable method to determine the DMI constant as materials parameter of asymmetric thin films is the crucial problem. Here, we put forth an experimental approach for the determination of the complete set of the micromagnetic parameters. Quasi-static Kerr microcopy observations of DW creep motion and equilibrium sizes of circular magnetic objects in combination with standard magnetometry are used to derive a consistent set of these materials parameters in polycrystalline ultrathin film systems, namely CrOx/Co/Pt stacks. The quantified micromagnetic model for these films identifies the circular magnetic objects, as seen by the optical microscopy, as ordinary bubble domains with homochiral walls. From micromagnetic calculations, the chiral skyrmions stabilized by the DMI in these films are shown to have diameters in the range 40-200nm, too small to be observed by optical microscopy.

Published

2017

14. Static and dynamic properties of noncollinear magnetized ferromagnetic films

Author

Jiménez-Bustamante, J., primary, Lindner, A., additional, Koyun, H. N., additional, Salikhov, R., additional, Lenz, K., additional, Lindner, J., additional, and Gallardo, R. A., additional

Published

2024

15. Spin-wave spectra in periodically surface-modulated ferromagnetic thin films

Author

Gallardo, R. A., Langer, M., Roldán-Molina, A., Schneider, T., Lenz, K., Lindner, J., and Landeros, P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

This article presents theoretical results for the dynamic response of periodically surface-modulated ferromagnetic thin films. For such system, the role of the periodic dipolar field induced by the modulation is addressed by using the plane-wave method. By controlling the geometry of the modulated volumes within the film, the frequency modes and spatial profiles of spin waves can be manipulated. The angular dependence of the frequency band-gaps unveils the influence of both dynamic and static magnetic charges, which reside in the edges of the etching periodic zones, and it is stablished that band-gap widths created by static magnetic charges are broader than the one created by dynamic magnetic charges. To corroborate the validity of the model, the theoretical results are compared with ferromagnetic resonance simulations, where a very good agreement is achieved between both methods. The theoretical model allows for a detailed understanding of the physics underlying these kind of systems, thereby providing an outlook to potential applications associated with magnonic crystals-based devices.

Published

2016

16. Negative-Energy Matter and the Direction of Time

Author

Lindner, J. C.

Subjects

Physics - General Physics

Abstract

This report offers a modern perspective on the problem of negative energy, based on a reexamination of the concept of time direction as it arises in a classical and quantum-mechanical context. From this analysis emerges an improved understanding of the general-relativistic stress-energy of matter as being a manifestation of local variations in the energy density of zero-point vacuum fluctuations. Based on those developments, a set of axioms is proposed from which are derived generalized gravitational field equations which actually constitute a simplification of relativity theory in the presence of negative-energy matter and a non-zero cosmological constant. Important clarifications are also achieved regarding the nature of the binary degrees of freedom of matter in the final stages of a gravitational collapse. Those results are then applied to provide original solutions to several long-standing problems in cosmology, including the problem of the nature of dark matter and dark energy, that of the origin of thermodynamic time asymmetry, and several other issues traditionally approached using inflation theory. Finally, we draw on those developments to provide significant new insights into the foundations of quantum theory, regarding, in particular, the problem of quantum non-locality, that of the emergence of time in quantum cosmology, as well as the question of the persistence of quasiclassicality following decoherence., Comment: Major revision with important changes to sections 2.8, 2.15, and 3.10 (including generalized gravitational field equations) with consequences developed in sections 4.2, 4.3, and 4.5 on cosmology

Published

2016

17. Examination of the evolution of iron oxide nanoparticles in flame spray pyrolysis by tailored in situ particle sampling techniques

Author

Tischendorf, R., Simmler, M., Weinberger, C., Bieber, M., Reddemann, M., Fröde, F., Lindner, J., Pitsch, H., Kneer, R., Tiemann, M., Nirschl, H., and Schmid, H.-J.

Published

2021

18. Spin caloritronic nano-oscillator.

Author

Safranski, C, Barsukov, I, Lee, HK, Schneider, T, Jara, AA, Smith, A, Chang, H, Lenz, K, Lindner, J, Tserkovnyak, Y, Wu, M, and Krivorotov, IN

Subjects

cond-mat.mes-hall

Abstract

Energy loss due to ohmic heating is a major bottleneck limiting down-scaling and speed of nano-electronic devices, and harvesting ohmic heat for signal processing is a major challenge in modern electronics. Here, we demonstrate that thermal gradients arising from ohmic heating can be utilized for excitation of coherent auto-oscillations of magnetization and for generation of tunable microwave signals. The heat-driven dynamics is observed in Y3Fe5O12/Pt bilayer nanowires where ohmic heating of the Pt layer results in injection of pure spin current into the Y3Fe5O12 layer. This leads to excitation of auto-oscillations of the Y3Fe5O12 magnetization and generation of coherent microwave radiation. Our work paves the way towards spin caloritronic devices for microwave and magnonic applications.Harvesting ohmic heat for signal processing is one of major challenges in modern electronics and spin caloritronics, but not yet well accomplished. Here the authors demonstrate a spin torque oscillator device driven by pure spin current arising from thermal gradient across an Y3Fe5O12/Pt interface.

Published

2017

19. Resonance-Based Sensing of Magnetic Nanoparticles Using Microfluidic Devices with Ferromagnetic Antidot Nanostructures

Author

Dowling, R., Narkovic, R., (0000-0001-5528-5080) Lenz, K., Oelschlägel, A., Lindner, J., Kostylev, M., Dowling, R., Narkovic, R., (0000-0001-5528-5080) Lenz, K., Oelschlägel, A., Lindner, J., and Kostylev, M.

Abstract

We demonstrated resonance-based detection of magnetic nanoparticles employing novel designs based upon planar (on-chip) microresonators that may serve as alternatives to conventional magnetoresistive magnetic nanoparticle detectors. We detected 130 nm sized magnetic nanoparticle clusters immobilized on sensor surfaces after flowing through PDMS microfluidic channels molded using a 3D printed mold. Two detection schemes were investigated: (i) indirect detection incorporating ferromagnetic antidot nanostructures within microresonators, and (ii) direct detection of nanoparticles without an antidot lattice. Using scheme (i), magnetic nanoparticles noticeably downshifted the resonance fields of an antidot nanostructure by up to 207 G. In a similar antidot device in which nanoparticles were introduced via droplets rather than a microfluidic channel, the largest shift was only 44 G with a sensitivity of 7.57 G/ng. This indicated that introduction of the nanoparticles via microfluidics results in stronger responses from the ferromagnetic resonances. The results for both devices demonstrated that ferromagnetic antidot nanostructures incorporated within planar microresonators can detect nanoparticles captured from dispersions. Using detection scheme (ii), without the antidot array, we observed a strong resonance within the nanoparticles. The resonance’s strength suggests that direct detection is more sensitive to magnetic nanoparticles than indirect detection using a nanostructure, in addition to being much simpler.

Published

2024

20. Coherent Magnons with Giant Nonreciprocity at Nanoscale Wavelengths

Author

Gallardo, R. A., Weigand, M., (0000-0002-3382-5442) Schultheiß, K., (0000-0002-3195-219X) Kakay, A., Mattheis, R., Raabe, J., Schütz, G., Deac, A. M., (0000-0002-4955-515X) Lindner, J., Wintz, S., Gallardo, R. A., Weigand, M., (0000-0002-3382-5442) Schultheiß, K., (0000-0002-3195-219X) Kakay, A., Mattheis, R., Raabe, J., Schütz, G., Deac, A. M., (0000-0002-4955-515X) Lindner, J., and Wintz, S.

Abstract

Non-reciprocal wave propagation arises in systems with broken time-reversal symmetry and is key to the functionality of devices, such as isolators or circulators, in microwave, photonic and acoustic applications. In magnetic systems, collective wave excitations known as magnon quasiparticles so far yielded moderate non-reciprocities, mainly observed by means of incoherent thermal magnon spectra, while their occurrence as coherent spin waves (magnon ensembles with identical phase) is yet to be demonstrated. Here, we report the direct observation of strongly non-reciprocal propagating coherent spin waves in a patterned element of a ferromagnetic bilayer stack with antiparallel magnetic orientations. We use time-resolved scanning transmission x-ray microscopy (TR-STXM) to directly image the layer-collective dynamics of spin waves with wavelengths ranging from 5 µm down to 100 nm emergent at frequencies between 500 MHz and 5 GHz. The experimentally observed non-reciprocity factor of these counter-propagating waves is greater than 10 with respect to both group velocities and specific wavelengths. Our experimental findings are supported by the results from an analytic theory and their peculiarities are further discussed in terms of caustic spin-wave focusing.

Published

2024

21. Laser-Induced Positional and Chemical Lattice Reordering Generating Ferromagnetism

Author

Pflug, T., Pablo-Navarro, J., Anwar, M. S., Olbrich, M., Magén, C., Ibarra, M. R., Potzger, K., (0000-0003-3893-9630) Faßbender, J., Lindner, J., Horn, A., Bali, R., Pflug, T., Pablo-Navarro, J., Anwar, M. S., Olbrich, M., Magén, C., Ibarra, M. R., Potzger, K., (0000-0003-3893-9630) Faßbender, J., Lindner, J., Horn, A., and Bali, R.

Abstract

Atomic scale reordering of lattices can induce local modulations of functional material properties, such as reflectance and ferromagnetism. Pulsed femtosecond laser irradiation enables lattice reordering in the picosecond range. However, the dependence of the phase transitions on the initial lattice order as well as the temporal dynamics of these transitions remain to be understood. This study investigates the laser-induced atomic reordering and the concomitant onset of ferromagnetism in thin Fe-based alloy films with vastly differing initial atomic orders. The optical response to single fs laser pulses on selected prototype systems, one that initially possesses positional disorder, Fe60V40, and a second system initially in a chemically ordered state, Fe60Al40, has been tracked with time. Despite the vastly different initial atomic orders the structure in both systems converges to a positionally ordered but chemically disordered state, accompanied by the onset of ferromagnetism. Time-resolved measurements of the transient reflectance combined with simulations of the electron and phonon temperature reveal that the reordering processes occur via the formation of a transient molten state with an approximate lifetime of 200 ps. These findings provide insights into fundamental processes involved in laser-induced atomic reordering, paving the way for controlling material properties in the picosecond range.

Published

2024

22. Multilayer Metamaterials with Ferromagnetic Domains Separated by Antiferromagnetic Domain Walls

Author

(0000-0001-8461-0743) Salikhov, R., (0000-0002-9971-0824) Samad, F., Schneider, S., Pohl, D., Rellinghaus, B., Böhm, B., Ehrler, R., (0000-0002-4955-515X) Lindner, J., Kiselev, N. S., (0000-0002-1351-5623) Hellwig, O., (0000-0001-8461-0743) Salikhov, R., (0000-0002-9971-0824) Samad, F., Schneider, S., Pohl, D., Rellinghaus, B., Böhm, B., Ehrler, R., (0000-0002-4955-515X) Lindner, J., Kiselev, N. S., and (0000-0002-1351-5623) Hellwig, O.

Abstract

Magnetic nano-objects possess great potential for more efficient data processing, storage, and neuromorphic-type applications. Using high perpendicular magnetic anisotropy synthetic antiferromagnets in the form of multilayer-based metamaterials, the antiferromagnetic interlayer exchange energy is purposefully reduced below the out-of-plane demagnetization energy, which controls magnetic domain formation. In this unusual magnetic energy regime, as demonstrated via macroscopic magnetometry and microscopic Lorentz transmission electron microscopy, it becomes possible to stabilize nanometer-scale stripe and bubble textures consisting of ferromagnetic out-of-plane domain cores separated by antiferromagnetic in-plane Bloch-type domain walls. This unique coexistence of mixed ferromagnetic/antiferromagnetic order on the nanometer scale opens so far unexplored perspectives in the architecture of magnetic domain landscapes as well as the design and functionality of individual magnetic textures, such as bubble domains with depth-wise alternating chirality.

Published

2024

23. Static and dynamic properties of noncollinear magnetized ferromagnetic films

Author

Jiménez-Bustamante, J., Lindner, A. A., (0000-0003-1814-2472) Koyun Yücel, H. N., (0000-0001-8461-0743) Salikhov, R., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., Gallardo, R. A., Jiménez-Bustamante, J., Lindner, A. A., (0000-0003-1814-2472) Koyun Yücel, H. N., (0000-0001-8461-0743) Salikhov, R., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., and Gallardo, R. A.

Abstract

The dynamic matrix method was employed to perform theoretical calculations for investigating both static and dynamic characteristics of thick ferromagnetic films. This approach considers situations where a noncollinear equilibrium magnetization exists along the thickness due to a thickness-dependent uniaxial anisotropy and inter- facial interactions in a synthetic antiferromagnet. In the former scenario, the study exposes a correlation between noncollinear static magnetization and a nonmonotonic dependence of ferromagnetic resonance frequency, where a frequency decrease is observed at low fields in the unsaturated regime. Regarding the synthetic antiferromagnet structure, the research demonstrates noncoherent magnetization rotation in the spin-flop regime, with twisted magnetization states influencing the critical and nucleation fields that define the spin-flop region. The results of the investigation were compared to the macrospin approach, where the magnetization is assumed to be uniform along the thickness. The study suggests that the contribution of noncollinear magnetic moments may mimic the role of the biquadratic interaction in the macrospin model, implying that such a biquadratic term may be over- estimated in coupled ferromagnetic films with thicknesses exceeding the material’s intrinsic exchange length. Finally, the model was compared with experimental data obtained from a Py/Ir/Py synthetic antiferromagnet, demonstrating that the theoretical consideration of a twisting equilibrium state of the magnetization precisely reproduces the observed dynamic and static properties of the nanostructure.

Published

2024

24. Irradiation-induced enhancement of Fe and Al magnetic polarizations in Fe60Al40 films

Author

Smekhova, A., Szyjka, T., La Torre, E., Ollefs, K., Eggert, B., Cöster, B., Wilhelm, F., Bali, R., (0000-0002-4955-515X) Lindner, J., Rogalev, A., Többens, D., Weschke, E., Luo, C., Chen, K., Radu, F., Schmitz-Antoniak, C., Wende, H., Smekhova, A., Szyjka, T., La Torre, E., Ollefs, K., Eggert, B., Cöster, B., Wilhelm, F., Bali, R., (0000-0002-4955-515X) Lindner, J., Rogalev, A., Többens, D., Weschke, E., Luo, C., Chen, K., Radu, F., Schmitz-Antoniak, C., and Wende, H.

Abstract

The rise of Fe magnetic moment, changes in Al electronic structure and a variation of Al magnetic polarization in thin films of transition metal aluminide Fe60Al40 have been probed through the order-disorder phase transition by soft x-ray absorption spectroscopy and x-ray resonant magnetic reflectivity in the extreme ultraviolet regime. In a course of the transition induced by 20 keV Ne+ irradiation with low fluences (∼1014 ions cm−2), x-ray magnetic circular dichroism spectra taken at the Fe L2,3 absorption edges at room and low temperatures revealed a pronounced increase of Fe 3d states spin-polarization. X-ray resonant magnetic reflectivity applied to the Al L2,3 and Fe M2,3 edges allowed to detect the magnetic polarization of Al atoms in the films. The changes in Al electronic structure have been seen by alteration of Al K edge x-ray absorption near edge structure. A difference in anisotropy fields for films before and after irradiation has been observed by element-specific hysteresis loops recorded at low temperatures in absorption and reflection geometries at the Fe L2,3 and M2,3 edges, respectively. An attempt to reduce the top oxide layer by an inductively coupled hydrogen plasma has shown a possibility to recover the chemically ordered phase.

Published

2024

25. Growth of Perpendicular Magnetic Anisotropy in Gallium-substituted Yttrium Iron Garnet Thin Films

Author

(0000-0001-5528-5080) Lenz, K., Gladii, O., Pablo-Navarro, J., Oelschlägel, A., Heller, R., (0000-0002-4955-515X) Lindner, J., Surzhenko, O., Dubs, C., (0000-0001-5528-5080) Lenz, K., Gladii, O., Pablo-Navarro, J., Oelschlägel, A., Heller, R., (0000-0002-4955-515X) Lindner, J., Surzhenko, O., and Dubs, C.

Abstract

We investigate the effect of Ga substitution on the magnetic properties of nanometer-thin Ga:YIG (Y_3Fe_5-xGa_xO_12) films grown by liquid phase epitaxy (LPE) [1,2]. The Ga content was varied between 1.1–1.3 f.u. and film thicknesses were 30 to 230 nm. The substitution of Fe sites by Ga ions reduces the remanent magnetization. Together with the tensile strain it causes a stronger out-of-plane uniaxial anisotropy (PMA) making thin Ga:YIG films perpendicularly magnetized. We also demonstrate that, independent of the thickness and of the substrate orientation, i.e. GGG(111) vs. (001), the PMA gradually increases with the Ga-content, resulting in a 14 times larger perpendicular anisotropy for the highest Ga content used in this study compared to pure YIG. This allows for an easy tuning of the PMA by variation of the Ga concentration. One feature of YIG almost remains: the Gilbertdamping increases only slightly with the amount of Ga. The inhomogeneous broadening shows a stronger dependence.

Published

2024

26. Data publication: Static and dynamic properties of noncollinear magnetized ferromagnetic films

Author

Jiménez-Bustamante, J., Lindner, A. A., (0000-0003-1814-2472) Koyun Yücel, H. N., (0000-0001-8461-0743) Salikhov, R., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., Gallardo, R. A., Jiménez-Bustamante, J., Lindner, A. A., (0000-0003-1814-2472) Koyun Yücel, H. N., (0000-0001-8461-0743) Salikhov, R., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., and Gallardo, R. A.

Abstract

Research data of the publication (FMR, VSM).

Published

2024

27. Anatomy of localized edge modes in laterally coupled waveguides

Author

(0000-0002-8553-7004) Iurchuk, V., Stienen, S., Lindner, J., (0000-0002-3195-219X) Kakay, A., (0000-0002-8553-7004) Iurchuk, V., Stienen, S., Lindner, J., and (0000-0002-3195-219X) Kakay, A.

Abstract

We present a systematic micromagnetic study of standing spin-wave modes in infinitely long Permalloy strips with rectangular cross-section. Using a finite-element dynamic-matrix method, we first calculate the eigenfrequencies and the corresponding eigenvectors (mode profiles), as a function of the in-plane magnetic field applied across the strip. The ferromagnetic resonance spectra is computed from the mode profiles, assuming a homogeneous radio-frequency excitation, equivalently to an experimental ferromagnetic resonance measurement. The investigation of the field-dependent mode profiles enables for the classification of the observed resonances, here focusing mostly on the \textit{true edge mode} localized at the vicinity of strip edges. Furthermore, we study the mode localization in pairs of 50-nm-thick Permalloy strips as a function of the strip width and their lateral separation. For closely spaced strips, the spatial profile of the quasi-uniform mode is substantially modified due to a significant hybridization with the edge-localized standing spin-wave modes of the neighbouring strip. We show that a wide-range-tunability of the localized edge-mode resonances can be achieved with a precise control of the magnetostatic coupling between the strips. Extreme sensitivity of the edge mode frequency on the bias field demonstrates a potential of the edge resonances for field sensing. Furthermore, for narrow strips ($\approx$100~nm in width), due to the reduced number of the allowed confined modes, a field-controllable switching between the resonances localized either in the strip center or at the edges of the strips can be achieved.

Published

2024

28. Equivalent initial bow imperfections for hollow sections

Author

Lindner, J., primary

Published

2021

29. Spin pumping at interfaces with ferro- and paramagnetic Fe60Al40 films acting as spin source and spin sink.

Author

Strusch, T., Lenz, K., Meckenstock, R., Bali, R., Ehrler, J., Lindner, J., Fassbender, J., Farle, M., Potzger, K., and Semisalova, A.

Subjects

MOTION picture acting, NUCLEAR spin, PHASE transitions, FERROMAGNETIC resonance, TRANSITION metal alloys, THIN films

Abstract

We present a study of spin pumping efficiency and determine the spin mixing conductance and spin diffusion length in thin bilayer films based on 3d transition metal alloy Fe60Al40. Due to its magnetostructural phase transition, Fe60Al40 can be utilized as a ferromagnetic (FM) or paramagnetic (PM) material at the same temperature depending on its structural order; thus a thin Fe60Al40 film can act as a spin source or a spin sink when interfaced with a paramagnet or a ferromagnet, respectively. Ferromagnetic resonance measurements were performed in a frequency range of 5–35 GHz on bilayer films composed of FM–Fe60Al40/Pd and PM–Fe60Al40/Ni80Fe20 (permalloy). The increase in damping with the thickness of the paramagnetic layer was interpreted as a result of spin pumping into the paramagnet. We determine the spin mixing conductance g P d ↑↓ = (3.8 ± 0.5) × 10 18 m − 2 at the FM–Fe60Al40/Pd interface and the spin diffusion length λ P d = 9.1 ± 2.0 nm in Pd. For the PM–Fe60Al40/permalloy interface, we find a spin mixing conductance g F e A l ↑↓ = (2.1 ± 0.2) × 10 18 m − 2 and a spin diffusion length λ F e A l = 11.9 ± 0.2 nm for PM–Fe60Al40. The demonstrated bi-functionality of the Fe60Al40 alloy in spin pumping structures may be promising for spintronic applications. [ABSTRACT FROM AUTHOR]

Published

2022

30. Reentrant superconductivity in superconductor/ferromagnetic-alloy bilayers

Author

Zdravkov, V. I., Kehrle, J., Obermeier, G., Gsell, S., Schreck, M., üller, C. M, von Nidda, H. A. Krug, Lindner, J., Moosburger-Will, J., Nold, E., Morari, R., Ryazanov, V. V., Sidorenko, A. S., Horn, S., Tidecks, R., and Tagirov, L. R.

Subjects

Condensed Matter - Superconductivity

Abstract

We studied the Fulde-Ferrell-Larkin-Ovchinnikov (FFLO) like state establishing due to the proximity effect in superconducting Nb/Cu41Ni59 bilayers. Using a special wedge-type deposition technique, series of 20-35 samples could be fabricated by magnetron sputtering during one run. The layer thickness of only a few nanometers, the composition of the alloy, and the quality of interfaces were controlled by Rutherford backscattering spectrometry, high resolution transmission electron microscopy, and Auger spectroscopy. The magnetic properties of the ferromagnetic alloy layer were characterized with superconducting quantum interference device (SQUID) magnetometry. These studies yield precise information about the thickness, and demonstrate the homogeneity of the alloy composition and magnetic properties along the sample series. The dependencies of the critical temperature on the Nb and Cu41Ni59 layer thickness, Tc(dS) and Tc(dF), were investigated for constant thickness dF of the magnetic alloy layer and dS of the superconducting layer, respectively. All types of non-monotonic behaviors of Tc versus dF predicted by the theory could be realized experimentally: from reentrant superconducting behavior with a broad extinction region to a slight suppression of superconductivity with a shallow minimum. Even a double extinction of superconductivity was observed, giving evidence for the multiple reentrant behavior predicted by theory. All critical temperature curves were fitted with suitable sets of parameters. Then, Tc(dF) diagrams of a hypothetical F/S/F spin-switch core structure were calculated using these parameters. Finally, superconducting spin-switch fabrication issues are discussed in detail in view of the achieved results., Comment: 34 pages, 9 figures

Published

2011

31. Interpreting Likert-type Scales, Summated Scales, Unidimensional Scales, and Attitudinal Scales: I neither Agree nor Disagree, Likert or Not.

Author

Lindner, J. R. and Lindner, N. J.

Subjects

*HUMAN behavior, *HUMAN experimentation, *BEHAVIORAL research, *PSYCHOLOGICAL research, *EDUCATION research

Abstract

This paper provides a rationale and convention for discussing the true limits and interpretation of data collected using unidimensional, summated, Likert-type, and attitudinal scales used in research investigating human behavior, sociology, education, psychology, and other related fields of study. All vague quantifiers must be described in methods and findings. The true limits of the scale and of each vague quantifier should be described. This information should be placed in the methods section. A five-point summated scale, for example, can be interpreted as follows: Strongly Agree = 5 - 4.51, Agree = 4.5 - 3.51, Neither Agree nor Disagree = 3.5 - 2.51, Disagree = 2.5 - 1.51, Strongly Disagree = 1.5 - 1. This paper also provides a rationale and convention for the use of nonstandardized effect size (ES) estimates to describe the magnitude and strength of the effect. This is accomplished by subtracting one summated M from another summated M and interpreted using the following convention: Small (ES = .19 and lower); Medium (ES = .20 - .49); and Large (ES = .50 and higher). The rationale for this is based on the intuitiveness of the measure, true limits of the scale, and scale intervals. [ABSTRACT FROM AUTHOR]

Published

2024

32. PB0705 Pharmacological Inhibition of Coagulation Factor XI Reduces Thromboinflammation in a Nonhuman Primate Model of Early Atherosclerosis

Author

Kohs, T., primary, Parra-Izquierdo, I., additional, Vu, H., additional, Jordan, K., additional, Hinds, M., additional, Shatzel, J., additional, Kievit, P., additional, Morgan, T., additional, Tassi Yunga, S., additional, Ngo, T., additional, Aslan, J., additional, Wallisch, M., additional, Lorentz, C., additional, Tucker, E., additional, Puy, C., additional, Gailani, D., additional, Lindner, J., additional, and McCarty, O., additional

Published

2023

33. PL01.4.A LATE BREAKING ABSTRACT: A LONG PEPTIDE VACCINE TARGETING THE CLONAL DRIVER MUTATION H3K27M IN ADULT PATIENTS WITH DIFFUSE MIDLINE GLIOMA

Author

Grassl, N, primary, Poschke, I, additional, Lindner, K, additional, Kromer, K, additional, Bunse, L, additional, Mildenberger, I, additional, Jaehne, K, additional, Haltenhof, G, additional, Tan, C, additional, Green, E, additional, Kessler, T, additional, Suwala, A, additional, Sahm, F, additional, Eisele, P, additional, Breckwoldt, M, additional, Vajkoczy, P, additional, Grauer, O, additional, Herrlinger, U, additional, Tonn, J, additional, Denk, M, additional, Bendszus, M, additional, von Deimling, A, additional, Winkler, F, additional, Wick, W, additional, Lindner, J, additional, Platten, M, additional, and Sahm, K, additional

Published

2023

34. Spin wave excitations: The main source of the temperature dependence of Interlayer exchange coupling in nanostructures

Author

Schwieger, S., Kienert, J., Lenz, K., Lindner, J., Baberschke, K., and Nolting, W.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Quantum mechanical calculations based on an extended Heisenberg model are compared with ferromagnetic resonance (FMR) experiments on prototype trilayer systems Ni_7/Cu_n/Co_2/Cu(001) in order to determine and separate for the first time quantitatively the sources of the temperature dependence of interlayer exchange coupling. Magnon excitations are responsible for about 75% of the reduction of the coupling strength from zero to room temperature. The remaining 25% are due to temperature effects in the effective quantum well and the spacer/magnet interfaces., Comment: accepted for publication in PRL

Published

2006

35. Mechanism of temperature dependence of the magnetic anisotropy energy in ultrathin Cobalt and Nickel films

Author

Kienert, J., Schwieger, S., Lenz, K., Lindner, J., Baberschke, K., and Nolting, W.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Temperature dependent FMR-measurements of Ni and Co films are analysed using a microscopic theory for ultrathin metallic systems. The mechanism governing the temperature dependence of the magnetic anisotropy energy is identified and discussed. It is reduced with increasing temperature. This behavior is found to be solely caused by magnon excitations., Comment: 3 pages, 4 figures III Joint European Magnetic Symposia, San Sebastian, Spain

Published

2006

36. Theoretical basis for a solution to the cosmic coincidence problem

Author

Lindner, J. C.

Subjects

General Relativity and Quantum Cosmology, Astrophysics

Abstract

Following a short discussion of some unresolved issues in the standard model of cosmology (considered to be a generic LCDM model with flat geometry and an early period of inflation), an update on the current state of research regarding the problem of negative energy is provided. Arguments are then given to the effect that traditional assumptions concerning the behavior of negative-action matter give rise to violations of both the principle of relativity and the principle of inertia. An alternative set of axioms is proposed that would govern the behavior of negative-action matter if it is to be considered a viable element of physical theories upon which cosmological models are build. A simple framework, based on general relativity and the proposed axioms, is elaborated which enables the formulation of quantitative predictions concerning the interaction between positive and negative-action bodies. Based on those developments, a solution is proposed to the problem of the discrepancy between current experimental and theoretical values of vacuum energy density (in any cosmological model), which may also constitute a solution to the problem of the unexplained coincidence between the (model-dependent) experimental values of vacuum energy density and present-day, average, matter energy density. It is also shown how irreversibility naturally arises in cosmological models derived in this context., Comment: This paper discusses an early attempt at solving the cosmic coincidence problem using a bi-metric theory of gravitation. A follow-up paper (arxiv:1608.01531) is available that extends and improves the original approach which underlies those developments

Published

2006

37. Use of sourdough fermentation to reducing FODMAPs in breads

Author

Menezes, L. A. A., Molognoni, L., de Sá Ploêncio, L. A., Costa, F. B. M., Daguer, H., and Dea Lindner, J. De

Published

2019

38. Control of Four-Magnon Scattering by Pure Spin Current in a Magnonic Waveguide

Author

Hache, T., primary, Körber, L., additional, Hula, T., additional, Lenz, K., additional, Kákay, A., additional, Hellwig, O., additional, Lindner, J., additional, Fassbender, J., additional, and Schultheiss, H., additional

Published

2023

39. Spin pumping into a partially compensated antiferromagnetic/paramagnetic insulator

Author

Buchner, M, primary, Lenz, K, additional, Ney, V, additional, Lindner, J, additional, and Ney, A, additional

Published

2023

40. 2024 State of the Journal Report.

Author

Roberts, T. G., Harder, A., and Lindner, J.

Subjects

AGRICULTURAL development, PUBLISHED articles, NATIONAL libraries

Abstract

This is the annual state of the journal report for Advancements in Agricultural Development. This report: (a) highlights key accomplishments from 2023, (b) discusses changes beginning in 2024, (c) shares journal statistics from 2023, (d) presents goals for 2024, and (e) lists reviewers for the year. 2023 (Volume 4) was a banner year for Advancements in Agricultural Development (AAD), with several milestones reached. First, we published our 100th article in August. Second, AAD was accepted for inclusion in AGRICOLA, the National Library of the U.S. Department of Agriculture (https://www.nal.usda.gov/agricola). Third, AAD was also selected for inclusion in the Cabells directory (https://cabells.com/), which will allow for generating journal analytics for citations and mentions. We also introduced a new style sheet for published articles, adding the submitted, accepted, and published dates for transparency. [ABSTRACT FROM AUTHOR]

Published

2024

41. Spin-wave nonreciprocity at the spin-flop transition region in synthetic antiferromagnets

Author

Gladii, O., primary, Salikhov, R., additional, Hellwig, O., additional, Schultheiss, H., additional, Lindner, J., additional, and Gallardo, R. A., additional

Published

2023

42. Evidenzbasierte Gesundheitsinformationen und Klimawandel: Was kann eine laienverständliche Gesundheitsinformation alles leisten?

Author

Gamradt, P, Höppner, C, Barth, M, Lindner, J, Marbach-Breitrück, E, Mibs, M, Seelig, M, Gamradt, P, Höppner, C, Barth, M, Lindner, J, Marbach-Breitrück, E, Mibs, M, and Seelig, M

Published

2023

43. The Asymmetry Quantification of Spin-Wave Dynamics in Single and Double Confined Rectangular Ni80Fe20 Microstrips

Author

Pile, S., Ney, A., (0000-0001-5528-5080) Lenz, K., Narkovic, R., Lindner, J., Wintz, S., Förster, J., Mayr, S., Weigand, M., Pile, S., Ney, A., (0000-0001-5528-5080) Lenz, K., Narkovic, R., Lindner, J., Wintz, S., Förster, J., Mayr, S., and Weigand, M.

Abstract

Research of the spin-wave (SW) dynamics in confined rectangular microstructures is important for the their potential use for information transport and processing [1]. The design of a microstructure can affect the SW be- havior, which can be used as a manipulating mechanism [2, 3]. The development of planar microresonators/mi- croantennas with a micro-coil (loop) allows for measuring FMR of a single ferromagnetic microstrip including resonance lines corresponding to the SW excitations [4, 5]. TR-STXM [6] with the use of the planar microres- onators enables direct, time-dependent imaging of the spatial distribution of the precessing magnetization across the nm-thin microstrips during FMR excitation at the GHz frequency range with elemental selectivity [7, 8] [...]

Published

2023

44. Structural and magnetic properties of thin cobalt films with mixed hcp and fcc phases

Author

(0009-0009-8149-2919) Patel, G. I., Ganss, F., (0000-0001-8461-0743) Salikhov, R., Stienen, S., Fallarino, L., Ehrler, R., Gallardo, R. A., (0000-0002-1351-5623) Hellwig, O., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., (0009-0009-8149-2919) Patel, G. I., Ganss, F., (0000-0001-8461-0743) Salikhov, R., Stienen, S., Fallarino, L., Ehrler, R., Gallardo, R. A., (0000-0002-1351-5623) Hellwig, O., (0000-0001-5528-5080) Lenz, K., and (0000-0002-4955-515X) Lindner, J.

Abstract

Cobalt is a magnetic material that finds extensive use in various applications, ranging from magnetic storage to ultrafast spintronics. Usually, it exists in two phases with different crystal lattices, namely in hexagonal close-packed (hcp) or face-centered cubic (fcc) structure. The crystal structure of Co films significantly influences their magnetic and spintronic properties. We report on the thickness dependence of the structural and magnetic properties of sputter-deposited Co on a Pt seed layer. It grows in an hcp lattice at low thicknesses, while for thicker films, it becomes a mixed hcp-fcc phase due to a stacking fault progression along the growth direction. The X-ray based reciprocal space map technique has been employed to distinguish and confirm the presence of both phases. Moreover, the precise determination of Landé’s g-factor by ferromagnetic resonance provides valuable insights into the structural properties. In our detailed experiments, we observe that a structural variation results in a nonmonotonic variation of the magnetic anisotropy along the thickness. The work offers information of great significance and insight for both fundamental physics and potential applications of thin films with perpendicular magnetic anisotropy.

Published

2023

45. Local magnetic patterning of nanostructures using cobalt and dysprosium focused ion beams

Author

(0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-3195-219X) Kakay, A., (0000-0003-3968-7498) Bischoff, L., Narkovic, R., Mazarov, P., (0000-0002-5200-6928) Hübner, R., Meyer, F., Pilz, W., Lindner, J., (0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-3195-219X) Kakay, A., (0000-0003-3968-7498) Bischoff, L., Narkovic, R., Mazarov, P., (0000-0002-5200-6928) Hübner, R., Meyer, F., Pilz, W., and Lindner, J.

Abstract

We present results for direct maskless magnetic patterning of ferromagnetic nanostructures using a special liquid metal alloy ion source for focused ion beam (FIB) systems. We used a Co36Nd64 alloy as the FIB source [1]. A Wien mass filter allows for quick switching between the ion species in the alloy without changing the FIB source. A 5000×1000×50 nm3 permalloy strip served as the sample. Using the FIB we implanted a 300-nm-wide track with Co ions (see Fig.1). We observed the Co-induced changes by measuring the sample with microresonator ferromagnetic resonance before and after the implantation. Structures as small as 30 nm can be implanted up to a concentration of 10 % near the surface. Such lateral resolution is hard to reach for other lithographic methods. This allows for easy magnetic modification of edge-localized spin waves. In another set of samples, we implanted Dy ions to locally increase the damping in a stripe pattern of ~120-nm-wide strips with 400 nm periodicity on a total area of 1×1 mm². Thus, the Gilbert damping parameter can be easily increased by one order of magnitude with a lateral resolution of about 100 nm. In contrast to electron beam lithography in combination with broad-beam ion implantation, the maskless FIB process does not require the cumbersome and difficult removal of the ion-hardened resist if optical measurements like BLS or TR-MOKE are needed.

Published

2023

46. All-electrical operation of a Curie-switch at room temperature

Author

(0000-0002-8553-7004) Iurchuk, V., Kozlov, O., Sorokin, S., (0000-0002-4885-799X) Zhou, S., Lindner, J., Reshetniak, S., Kravets, A., Polishchuk, D., Korenivski, V., (0000-0002-8553-7004) Iurchuk, V., Kozlov, O., Sorokin, S., (0000-0002-4885-799X) Zhou, S., Lindner, J., Reshetniak, S., Kravets, A., Polishchuk, D., and Korenivski, V.

Abstract

We present all-electrical operation of a Fe$_x$Cr$_{1-x}$-based Curie switch at room temperature. More specifically, we study the current-induced thermally-driven transition from ferromagnetic to antiferromagnetic Ruderman-Kittel-Kasuya-Yosida (RKKY) indirect coupling in a Fe/Cr/Fe$_{17.5}$Cr$_{82.5}$/Cr/Fe multilayer. Magnetometry measurements at different temperatures show that the transition from the ferromagnetic to the antiferromagnetic coupling at zero field is observed at $\sim$325K. Analytical modelling confirms that the observed temperature-dependent transition from indirect ferromagnetic to indirect antiferromangetic interlayer exchange coupling originates from the modification of the effective interlayer exchange constant through the ferromagnetic-to-paramagnetic transition in the Fe$_{17.5}$Cr$_{82.5}$ spacer with minor contributions from the thermally-driven variations of the magnetization and magnetic anisotropy of the Fe layers. Room-temperature current-in-plane magnetotransport measurements on the patterned Fe/Cr/Fe$_{17.5}$Cr$_{82.5}$/Cr/Fe strips show the transition from the 'low-resistance' parallel to the 'high-resistance' antiparallel remanent magnetization configuration, upon increased probing current density. Quantitative comparison of the switching fields, obtained by magnetometry and magnetotransport, confirms that the Joule heating is the main mechanism responsible for the observed current-induced resistive switching.

Published

2023

47. Spin wave non-reciprocity at the spin-flop transition region in synthetic antiferromagnets

Author

Gladii, O., (0000-0001-8461-0743) Salikhov, R., (0000-0002-1351-5623) Hellwig, O., (0000-0002-6727-5098) Schultheiß, H., Lindner, J., Gallardo, R., Gladii, O., (0000-0001-8461-0743) Salikhov, R., (0000-0002-1351-5623) Hellwig, O., (0000-0002-6727-5098) Schultheiß, H., Lindner, J., and Gallardo, R.

Abstract

We investigate the frequency non-reciprocity in CoFeB/Ru/CoFeB synthetic antiferromagnets near the spin-flop transition region, where the magnetic moments in the two ferromagnetic layers are non-collinear. Using conventional Brillouin light scattering, we perform systematic measurements of the frequency non-reciprocity as a function of an external magnetic field. For the antiparallel alignment of the magnetic moments in the two layers, we observe a significant frequency non-reciprocity of up to a few GHz, which vanishes when the relative magnetization orientation switches into the parallel configuration at saturation. A non-monotonous dependence of the frequency non-reciprocity is found in the region where the system transitions from the antiparallel to the parallel orientation, with a maximum frequency shift around the spin-flop critical point. This non-trivial dependence of the non-reciprocity is attributed to the non-monotonous dependence of the dynamic dipolar interaction, which is the main factor that causes asymmetry in the dispersion relation. Furthermore, we found that the sign of the frequency shift changes even without switching the polarity of the bias field. These results show that one can precisely control the non-reciprocal propagation of spin waves via field-driven magnetization reorientation.

Published

2023

48. Control of Four-Magnon Scattering by Pure Spin Current in a Magnonic Waveguide

Author

Hache, T., (0000-0001-8332-9669) Körber, L., Hula, T., (0000-0001-5528-5080) Lenz, K., (0000-0002-3195-219X) Kakay, A., (0000-0002-1351-5623) Hellwig, O., Lindner, J., (0000-0003-3893-9630) Faßbender, J., (0000-0002-6727-5098) Schultheiß, H., Hache, T., (0000-0001-8332-9669) Körber, L., Hula, T., (0000-0001-5528-5080) Lenz, K., (0000-0002-3195-219X) Kakay, A., (0000-0002-1351-5623) Hellwig, O., Lindner, J., (0000-0003-3893-9630) Faßbender, J., and (0000-0002-6727-5098) Schultheiß, H.

Abstract

We use a pure spin current originating from the spin Hall effect to generate a spin-orbit torque strongly reducing the effective damping in an adjacent ferromagnet. Because of additional microwave excitation, large spin-wave amplitudes are achieved exceeding the threshold for four-magnon scattering, thus resulting in additional spin-wave signals at discrete frequencies. Two or more modes are generated below and above the directly pumped mode with equal frequency spacing. It is shown how this nonlinear process can be controlled in magnonic waveguides by the applied dc current and the microwave pumping power. The sudden onset of the nonlinear effect after exceeding the thresholds can be interpreted as a spiking phenomenon, which makes the effect potentially interesting for neuromorphic computing applications. Moreover, we investigated this effect under microwave frequency and external field variation. The appearance of the additional modes was investigated in the time domain, revealing a time delay between the directly excited and the simultaneously generated nonlinear modes. Furthermore, spatially resolved measurements show different spatial decay lengths of the directly pumped mode and nonlinear modes.

Published

2023

49. Terahertz harmonic generation from graphite pencil drawings

Author

(0000-0002-5142-5565) Arshad, A., (0000-0003-1814-2472) Koyun, H. N., (0000-0001-8461-0743) Salikhov, R., Gensch, M., (0000-0002-5928-7996) Ilyakov, I., (0000-0003-1200-2866) Ponomaryov, O., (0000-0001-7111-4206) Prajapati, G. L., Mavridou, K., Lindner, J., (0000-0001-6211-0158) Deinert, J.-C., Ünlü, C., (0000-0002-4886-0654) Oliveira, T., (0000-0002-2290-1016) Kovalev, S., (0000-0002-5142-5565) Arshad, A., (0000-0003-1814-2472) Koyun, H. N., (0000-0001-8461-0743) Salikhov, R., Gensch, M., (0000-0002-5928-7996) Ilyakov, I., (0000-0003-1200-2866) Ponomaryov, O., (0000-0001-7111-4206) Prajapati, G. L., Mavridou, K., Lindner, J., (0000-0001-6211-0158) Deinert, J.-C., Ünlü, C., (0000-0002-4886-0654) Oliveira, T., and (0000-0002-2290-1016) Kovalev, S.

Abstract

We study the third harmonic generation (THG) of graphite layers on paper substrate upon excitation with intense (up to 100 kV/cm) narrowband terahertz (THz) pulses. Highest THG efficiencies are comparable with those of CVD-grown single-layer graphene. Samples were hand-drawn, using commercially available pencils. The THG response showed a high sensitivity regarding the hatching direction relative to the THz polarization orientation. Using Raman spectroscopy, we confirmed the occurrence of graphene-like structures in the samples. Our findings demonstrate the feasibility of virtually no cost and easy to fabricate materials for THz nonlinear optics.

Published

2023

50. Transport properties of Fe60Al40 during the B2 to A2 structural phase transition

Author

(0000-0002-7557-0345) Sorokin, S., (0000-0002-1754-4229) Anwar, M. S., (0000-0001-7192-716X) Hlawacek, G., Boucher, R., Salgado Cabaco, J., Potzger, K., Lindner, J., (0000-0003-3893-9630) Faßbender, J., Bali, R., (0000-0002-7557-0345) Sorokin, S., (0000-0002-1754-4229) Anwar, M. S., (0000-0001-7192-716X) Hlawacek, G., Boucher, R., Salgado Cabaco, J., Potzger, K., Lindner, J., (0000-0003-3893-9630) Faßbender, J., and Bali, R.

Abstract

The variation of transport behaviour in a mesoscopic Fe60Al40 wire, initially possessing the ordered B2-phase structure, has been observed while inducing a phase transition to the disordered A2 structure. Gradual disordering was achieved using a highly focused beam of Ne+-ions. Both electrical resistance and anomalous Hall effect were measured in parallel with the local ion irradiation. Both the normal and Hall resistivity show a peak as a function of fluence. Moreover, the relationship between Hall resistivity and normal resistivity reconfirms the presence of two distinct regimes in the transition. Furthermore, field-dependence and temperature-dependence measurements were used to identify that it is necessary to consider the effect of scattering from magnetic clusters to understand these different regimes in transport properties.

Published

2023